WO2022016794A1

WO2022016794A1 - Drink dispenser

Info

Publication number: WO2022016794A1
Application number: PCT/CN2020/137688
Authority: WO
Inventors: 倪祖根
Original assignee: 莱克电气绿能科技(苏州)有限公司
Priority date: 2020-07-21
Filing date: 2020-12-18
Publication date: 2022-01-27
Also published as: CN113951724A

Abstract

A drink dispenser (200), comprising: a water purification mechanism, which comprises a filter assembly (203) and a water purification tank (204) connected to a water outlet end of the filter assembly (203); a heating mechanism (290) for heating purified water that flows through the heating mechanism (290); a drink treatment mechanism comprising a cup body assembly (210); a thermally insulated container (220); a water outlet device (201); a water pump assembly comprising a first water pump (250) which allows the purified water in the water purification tank (204) to be pumped out and flow through the heating mechanism (290), and a second water pump (280) which allows the water in the thermally insulated container (220) to be pumped out and flow through the heating mechanism (290); and a valve assembly (230), which can selectively control the delivery of the purified water flowing through the heating mechanism (290) to the water outlet device (201), the cup body assembly (210) or the heat preservation container (220). The drink dispenser (200) can have the functions of water purification, drink treatment and thermal insulation.

Description

beverage machine

technical field

The invention relates to the field of beverage machines, in particular to a beverage machine.

Background technique

The statements herein merely provide background information related to the present application and do not necessarily constitute prior art.

With the improvement of people's living needs, various beverage machines are more and more widely used in people's daily life. Specifically, some beverage machines have a beverage processing function such as making tea, some beverage machines have a water purification function, and some beverage machines have a heat preservation function. However, the traditional beverage machine has a single function, which is difficult to meet the diverse needs of people.

SUMMARY OF THE INVENTION

Based on this, it is necessary to provide a beverage machine that can simultaneously purify water, treat beverages, and keep warm.

A beverage machine, comprising:

a water purification mechanism, including a filter assembly and a water purification tank connected to the water outlet of the filter assembly;

a heating mechanism for heating the purified water flowing through the heating mechanism;

Beverage processing mechanism, including cup assembly;

insulated container;

water outlet;

A water pump assembly, comprising a first water pump for pumping out the clean water in the clean water tank and flowing through the heating mechanism, and a first water pump for pumping out the water in the heat preservation container and flowing through the heating mechanism two water pumps;

The valve assembly can selectively control the water flowing through the heating mechanism to be delivered to the water outlet, the cup assembly or the heat preservation container.

The above-mentioned beverage machine filters the raw water through the water purification mechanism to have a water purification function; through the beverage processing mechanism, the purified water and other raw materials delivered to the cup assembly are processed to generate beverages, that is, it has a beverage processing function; The purified water heated by the heating mechanism is subjected to heat preservation treatment through the heat preservation container, that is, the heat preservation function is provided. Therefore, the above-mentioned beverage machine can have the functions of water purification, beverage processing and heat preservation at the same time.

In one of the embodiments, it further includes a cover, the cover has an inner cavity, the water purification mechanism, the heating mechanism, the heat preservation container, the water pump assembly and the valve assembly are all located in the cover the inner cavity of the shell; the housing includes a front panel, the front panel has an inwardly recessed recessed area; the beverage processing mechanism is located on the outer surface of the recessed area of the front panel.

In one of the embodiments, the heating mechanism is located on the inner side of the front panel and is arranged adjacent to the front panel.

In one of the embodiments, the heat preservation container is located inside the front panel, and is arranged adjacent to the front panel;

The housing also includes a first side panel adjacent to the front panel; the first water pump is located inside the first side panel and adjacent to both the second water pump and the first side panel The water purification tank is located on the inner side of the front panel and is arranged adjacent to the front panel.

In one embodiment, the heating mechanism, the heat preservation container and the water pump assembly are all located on the bottom side of the clean water tank.

In one of the embodiments, it also includes a base plate assembly and a raw water tank installation position; the raw water tank installation position and the cover are both fixed on the base plate assembly; the raw water tank installation position is in the same direction as the cover. are arranged adjacent to each other, and the original water tank installation position is located on the side of the housing away from the front panel;

Along the installation position of the raw water tank and the arrangement direction of the cover on the bottom plate assembly, the filter assembly is located between the clean water tank and the installation position of the raw water tank.

In one embodiment, the valve assembly includes:

A main body, the main body has a first cavity, a second cavity, a first communication channel communicating with the first cavity and the second cavity, a water inlet communicating with the first cavity, and a water inlet communicating with the first cavity. a first water outlet communicated with the first cavity, a second water outlet communicated with the second cavity, and a third water outlet communicated with the second cavity;

The first electromagnetic drainage unit can be switched between a first state and a second state; when the first electromagnetic drainage unit is in the first state, the first communication channel is blocked, and the first water outlet is connected to the first water outlet. A cavity is connected; when the first electromagnetic drainage unit is in the second state, the first water outlet is blocked, and the first cavity and the second cavity are connected through the first communication channel; as well as

The second electromagnetic drainage unit can be switched between the third state and the fourth state; when the second electromagnetic drainage unit is in the third state, the third water outlet is blocked, and the second water outlet is connected to the third water outlet. The two cavities are connected; when the second electromagnetic drainage unit is in the fourth state, the second water outlet is blocked, and the third water outlet is connected through the second cavity;

Wherein, the first water outlet is communicated with the water outlet, the second water outlet is communicated with the insulation container, and the third water outlet is communicated with the cup assembly; When the first electromagnetic drainage unit is in the first state, the first water outlet discharges water, and the water flowing out of the first water outlet flows out from the water outlet; When the drainage unit is in the second state and the second electromagnetic drainage unit is in the third state, the second water outlet discharges water, and the water flowing out of the second water outlet flows into the heat preservation container; When the water, the first electromagnetic drainage unit is in the second state, and the second electromagnetic drainage unit is in the fourth state, the third water outlet flows out water, and the water flowing out of the third water outlet flows into the cup body components.

In one embodiment, the first electromagnetic drainage unit includes a first mover, a first coil sleeved on the first mover, located in the first cavity and connected to the first mover A fixedly connected first plug and a first reset piece; the first coil is not energized, and the first mover is reset under the action of the first reset piece, so that the first communication channel and all One of the first water outlets is blocked by the first plug; the first coil is energized, and the first mover moves to drive the first plug to move, so as to make the first communication channel and the first water outlet is blocked by the first plug;

And/or, the second electromagnetic drainage unit includes a second mover, a second coil sleeved on the second mover, a coil located in the second cavity and fixedly connected to the second mover. The second plug and the second reset part of the device; the second coil is not energized, and the second mover is reset under the action of the second reset part, so that the second communication channel and the second One of the water outlets is blocked by the second plug; the second coil is energized, and the second mover moves to drive the second plug to move, so that the second communication channel and the The other side of the second water outlet is blocked by the second plug.

In one embodiment, the beverage processing mechanism further includes a water outlet seat disposed on the bottom side of the cup assembly; the water outlet seat includes:

chassis;

a water outlet, which is movably arranged on the chassis; the water outlet moves to switch between the first position and the second position;

The top piece has a first connecting portion rotatably connected with the bottom frame, a second connecting portion deviating from the first connecting portion, and a top portion deviating from the first connecting portion; the top piece is rotatable to make The top is switched between the jacking position and the falling position; when the top is switched from the falling position to the jacking position, the water outlet is jacked up to the first position; When the rising position is switched to the falling position, the water outlet can be forced to fall back to the second position; and

an electric drive assembly for driving the second connecting part of the top piece to move so that the top piece is rotated until the top is in a jacked-up position;

The bottom of the cup assembly is provided with a water outlet docked with the water outlet; the water outlet is provided with a valve core;

Wherein, when the water outlet moves from the second position to the first position, the water outlet drives the valve core to move in the first direction; after the valve core is separated from the driving force of the water outlet, the Can automatically move to a second direction; the first direction is a direction extending along the water outlet and pointing to the inner cavity of the cup assembly, extending along the water outlet and away from the inner cavity of the cup assembly One of the directions, the second direction is a direction extending along the water outlet and pointing to the inner cavity of the cup assembly, and a direction extending along the water outlet and away from the inner cavity of the cup assembly one of the other.

In one of the embodiments, a water collecting assembly with thermal insulation effect is also included.

In one embodiment, the water collection assembly includes:

a water collection box, the water collection box has a water collection cavity and an installation cavity sealed and isolated from the water collection cavity;

A heating component, the heating component is arranged in the installation cavity; or, the heating component is arranged on the installation cavity, and the heating component has pins that are sealingly connected to the installation cavity.

In one embodiment, the water collection assembly further comprises a heat preservation placing table; the heat preservation placing table is arranged on the water collecting box and is in thermal contact with the heating element.

In one embodiment, the water collection box has an inner cavity; the inner cavity of the water collection box is provided with a partition wall; the partition wall divides the inner cavity of the water collection box into a water collection cavity and an installation cavity .

In one of the embodiments, the installation cavity has a top wall and a bottom wall; the heating component is arranged on the top wall of the installation cavity and is spaced from the bottom wall of the installation cavity;

The heat preservation placing table, the partition wall and the cavity wall of the inner cavity of the water collecting box enclose the installation cavity; the surface of the heat preservation placing table enclosing the installation cavity constitutes the ceiling of the installation cavity. wall.

In one embodiment, a plug electrically connected to the heating component is fixed on the water collecting box, and the beverage machine further includes a socket matching the plug; the plug is detachably connected to the socket .

In one of the embodiments, a power adapter matched with the plug is also included.

In one of the embodiments, it further includes a beverage storage container that can be placed on the water collecting box; the beverage storage container includes a first cup body and a first cup cover matched with the first cup body; the The first cup cover has a water inlet hole that communicates with the cup cavity of the first cup body; the beverage flowing out of the beverage processing mechanism can directly flow into the beverage storage container through the water inlet hole.

In one embodiment, the water purification tank has a closed water purification chamber; the water purification chamber has a water outlet channel; the beverage machine further includes two ends in sealed communication with the water purification chamber and the water outlet channel, respectively. the first airway.

In one embodiment, the first air conduit can guide the steam flowing through the water outlet channel of the water purification chamber into the water purification chamber.

In one embodiment, the water purification chamber has an exhaust port communicating with the water outlet channel, and one end of the first air conduit is sealed and sleeved on the exhaust port.

In one of the embodiments, the exhaust port has an exhaust channel communicating with the water outlet channel; the beverage machine further includes a bottom plate assembly; the exhaust channel extends in a direction perpendicular to the bottom plate assembly, and The exhaust channel is located at the top of the water purification chamber.

In one of the embodiments, the heat preservation container has a closed heat preservation cavity; the beverage machine further includes a second air conduit whose ends are in sealed communication with the heat preservation cavity and the water purification cavity, respectively.

In one of the embodiments, the cup body assembly includes a second cup body and a second cup cover matched with the second cup body; the second cup cover includes:

a cover body, the cover body has a cover surface; and

The blocking piece is in sealing contact with at least a part of the edge of the cover joint surface of the cover body; the blocking piece and the cover joint surface form a shut-off groove.

Description of drawings

FIG. 1 is a schematic structural diagram of a beverage machine according to an embodiment of the present invention.

FIG. 2 is a partial structural schematic diagram of the beverage machine in FIG. 1 .

FIG. 3 is a schematic structural diagram of the inside of the housing of the beverage machine in FIG. 1 in a view direction.

FIG. 4 is a schematic structural diagram of the beverage machine shown in FIG. 1 in another view direction.

FIG. 5 is a schematic structural diagram of the beverage machine shown in FIG. 4 after removing the first side panel.

FIG. 6 is a schematic structural diagram of the valve assembly in FIG. 3 .

FIG. 7 is an exploded view of the valve assembly shown in FIG. 6 .

FIG. 8 is a cross-sectional view of the first electromagnetic drainage unit in the valve assembly shown in FIG. 6 when it is in a first state.

FIG. 9 is a cross-sectional view of another section of the valve assembly shown in FIG. 6 .

FIG. 10 is a cross-sectional view of the upper valve body in FIG. 7 .

FIG. 11 is a cross-sectional view of the lower valve body in FIG. 7 .

12 is a cross-sectional view of the valve assembly shown in FIG. 6 when the first electromagnetic drainage unit is in a second state and the second electromagnetic drainage unit is in a third state.

13 is a cross-sectional view of the valve assembly shown in FIG. 6 when the first electromagnetic drainage unit is in a second state and the second electromagnetic drainage unit is in a fourth state.

FIG. 14 is a schematic structural diagram of a water outlet according to an embodiment of the present invention.

FIG. 15 is a schematic diagram of the internal structure of the water outlet shown in FIG. 14 .

FIG. 16 is a schematic structural diagram of the rotating member in FIG. 15 .

FIG. 17 is a schematic structural diagram of the top piece in FIG. 15 .

FIG. 18 is a schematic view of the structure of the top piece in FIG. 17 in another direction.

FIG. 19 is a schematic structural diagram of the top of the top member in FIG. 15 when the top is in the jacked-up position.

FIG. 20 is a schematic structural diagram of the water outlet in FIG. 15 .

FIG. 21 is a cross-sectional view of the water outlet in FIG. 15 .

FIG. 22 is a schematic structural diagram of the valve core in the second cup in FIG. 2 when the valve core is in a closed state. .

FIG. 23 is a schematic structural diagram of the valve core in the second cup body in FIG. 2 when the valve core is in an open state.

FIG. 24 is a schematic structural diagram of the water collecting assembly in FIG. 1 .

FIG. 25 is an exploded view of the water collection assembly described in FIG. 24 .

FIG. 26 is a schematic view of the structure of the heat preservation placing table in FIG. 24 .

FIG. 27 is a cross-sectional view taken along the line A-A of the water collecting assembly shown in FIG. 24 .

FIG. 28 is a schematic diagram of the connection relationship between the two ends of the first air duct and the water purification tank and the water outlet seat, respectively.

FIG. 29 is a schematic structural diagram of the water outlet in FIG. 1 .

Figure 30 is a schematic structural diagram of the inside of the casing of the beverage machine in another view direction.

FIG. 31 is a schematic structural diagram of the second cup cover in the figure.

FIG. 32 is a bottom view of the second cup cover shown in FIG. 30 .

33 is a schematic structural diagram of a beverage storage container of a beverage machine according to an embodiment of the present invention.

200, beverage machine; 210, cup body assembly; 211, water outlet; 212, second cup body; 214, second cup lid; 2125, valve core; 220, insulation container; 230, valve assembly; 250, first water pump ; 280, second water pump; 290, heating mechanism; 201, water outlet; 2011, water outlet; 2013, exhaust port; 2014, exhaust channel; 2015, outlet; 202, housing; 2022, front panel; 2023, 2024, the first side panel; 203, the filter assembly; 204, the water purification tank; 2041, the water purification chamber; 2042, the first air duct; 2043, the second air duct; 205, the bottom plate assembly; Installation position; 1. Water collection assembly; 101, Water collection box; 1011, Water collection cavity; 1012, Inner cavity; 1013, Installation cavity; 10131, Top wall; 10133, Bottom wall; 1014, Partition wall; 102, Heating component ; 103, heat preservation placing table; 1031, placing surface; 104, sealing ring; 1041, slot; 105, through groove; 106, plug; 107, socket; 108, connection channel; 2, beverage storage container; 21, first Cup body; 23, first cup lid; 231, water inlet; 310, lid body; 311, lid joint surface; 312, drainage groove; 313, first installation structure; 315, perforation; 317, groove; 320, 330, stopper; 331, stop surface; 332, first side; 334, second side; 333, outer surface; 10, main body; 111, first cavity; 112, second cavity; 113, 114, the first communication channel; 115, the second communication channel; 116, the water inlet; 117, the first water outlet; 118, the second water outlet; 119, the third water outlet; 1111, the middle cavity ; 1112, the first accommodation space; 131, the first mover; 133, the first coil; 135, the first plug; 137, the first reset piece; 139, the first connector; 151, the second mover; 153, the second coil; 155, the second plug; 157, the second reset piece; 10, the first flow blocking piece; 20, the second flow blocking piece; 30, the upper valve body; 40, the lower valve body; 50, Support frame; 60, sealing ring; 70, sealing piece; 80, skeleton; 90, pressure plate; 400, water outlet; 410, bottom frame; 411, cup body assembly mounting part; 413, mounting hole; 430, water outlet; 431 433, push part; 435, limit piece; 436, anti-dropping part; 450, top piece; 451, first connecting part; 453, second connecting part; 454, abutting protrusion; 455, Top; 4551, via hole; 470, electric drive assembly; 471, rotating part; 4711, protrusion; 4713, depression; 473, motor; 490, cup assembly identification mechanism; a, first axis.

detailed description

In order to make the above objects, features and advantages of the present invention more clearly understood, the specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, the present invention can be implemented in many other ways different from those described herein, and those skilled in the art can make similar improvements without departing from the connotation of the present invention. Therefore, the present invention is not limited by the specific embodiments disclosed below.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", " Back, Left, Right, Vertical, Horizontal, Top, Bottom, Inner, Outer, Clockwise, Counterclockwise, Axial , "radial", "circumferential" and other indicated orientations or positional relationships are based on the orientations or positional relationships shown in the accompanying drawings, and are only for the convenience of describing the present invention and simplifying the description, rather than indicating or implying the indicated device or Elements must have a particular orientation, be constructed and operate in a particular orientation and are therefore not to be construed as limitations of the invention.

In addition, the terms "first" and "second" are only used for descriptive purposes, and should not be construed as indicating or implying relative importance or implying the number of indicated technical features. Thus, a feature delimited with "first", "second" may expressly or implicitly include at least one of that feature. In the description of the present invention, "plurality" means at least two, such as two, three, etc., unless otherwise expressly and specifically defined.

In the present invention, unless otherwise expressly specified and limited, the terms "installed", "connected", "connected", "fixed" and other terms should be understood in a broad sense, for example, it may be a fixed connection or a detachable connection , or integrated; it can be a mechanical connection or an electrical connection; it can be directly connected or indirectly connected through an intermediate medium, it can be the internal connection of two elements or the interaction relationship between the two elements, unless otherwise specified limit. For those of ordinary skill in the art, the specific meanings of the above terms in the present invention can be understood according to specific situations.

In the present invention, unless otherwise expressly specified and limited, a first feature "on" or "under" a second feature may be in direct contact between the first and second features, or the first and second features indirectly through an intermediary get in touch with. Also, the first feature being "above", "over" and "above" the second feature may mean that the first feature is directly above or obliquely above the second feature, or simply means that the first feature is level higher than the second feature. The first feature being "below", "below" and "below" the second feature may mean that the first feature is directly below or obliquely below the second feature, or simply means that the first feature has a lower level than the second feature.

It should be noted that when an element is referred to as being "fixed to" or "disposed on" another element, it can be directly on the other element or an intervening element may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical", "horizontal", "upper", "lower", "left", "right" and similar expressions used herein are for the purpose of illustration only and do not represent the only embodiment.

Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the technical field to which this application belongs. The terms used herein in the specification of the application are for the purpose of describing specific embodiments only, and are not intended to limit the application. The technical features of the above embodiments can be combined arbitrarily. In order to make the description simple, all possible combinations of the technical features in the above embodiments are not described. However, as long as there is no contradiction in the combination of these technical features It is considered to be the range described in this specification.

As shown in FIGS. 1 to 32 , a beverage machine provided by an embodiment of the present invention includes a water purification mechanism, a heating mechanism 290 , a beverage processing mechanism, a heat preservation container 220 , a water outlet 201 , a water pump assembly, and a valve assembly 230 .

1 to 5 , the water purification mechanism includes a filter assembly 203 and a water purification tank 204 connected to the water outlet of the filter assembly 203 . The heating mechanism 290 is used for heating the purified water flowing through the heating mechanism 290 . The beverage handling mechanism includes a cup assembly 210 . The water pump assembly includes a first water pump 250 for pumping out the clean water in the clean water tank 204 and flowing through the heating mechanism 290 , and a second water pump 280 for pumping out the water in the heat preservation container 220 and flowing through the heating mechanism 290 . The valve assembly 230 can selectively control the purified water flowing through the heating mechanism 290 to be delivered to the water outlet 201 , the cup assembly 210 or the heat preservation container 220 .

The above-mentioned beverage machine filters the raw water through the water purification mechanism to have a water purification function; the beverage processing mechanism processes the purified water and other raw materials delivered to the cup body assembly 210 to generate beverages, that is, has a beverage processing function The heat preservation treatment is performed on the purified water heated by the heating mechanism 290 through the heat preservation container 220, so that when the user needs hot water exceeding the preset temperature, the hot water can be quickly produced with a large flow and save the user time. Therefore, the above-mentioned beverage machine can simultaneously have the functions of water purification, beverage processing, heat preservation, and rapid hot water production with large flow.

Specifically, the raw water is first filtered through the filter assembly 203, and then flows into the water purification tank 204 for use. The clean water in the clean water tank 204 is pumped out by the first water pump 250 and flows through the heating mechanism 290 . The heating mechanism 290 determines whether to perform heating according to the control instruction, and then the control valve assembly 230 makes the clean water flowing through the heating mechanism 290 . It is transported to the water outlet 201 , the cup assembly 210 or the heat preservation container 220 . That is, the purified water flowing through the heating mechanism 290 can be directly used for drinking, used for making drinks, or stored in the thermal insulation container 220 . The water in the heat preservation container 220 can also be pumped out by the second water pump 280 and flow through the heating mechanism 290. The heating mechanism 290 determines whether to perform heating according to the control instruction, and then the purified water flowing through the heating mechanism 290 is made through the control valve assembly 230. It is transported to the water outlet 201 , the cup assembly 210 or the heat preservation container 220 . That is, the purified water in the thermal insulation container 220 can be heated again, and after heating, it can be directly used for drinking, used to make drinks, or stored in the thermal insulation container 220 again.

Therefore, in the above water dispenser, the water flowing through the heating mechanism 290 is filtered, so that the drinking water directly used for drinking output through the water outlet 201 is more suitable for drinking. In addition, the filtered water is used to make drinks, which can better increase the taste of drinks.

In addition, it can be understood that the heating mechanism 290 is used to heat the purified water flowing therethrough. However, when the heating mechanism 290 does not work, the purified water flowing through the heating mechanism 290 cannot be heated, so the purified water flowing through the heating mechanism 290 can be controlled by the valve assembly 230 to be delivered to the water outlet 201 to obtain purified water at room temperature . In addition, if the purified water flowing through the heating mechanism 290 comes from the thermal insulation container 220, the purified water with appropriate temperature can flow out through the water outlet 201, which is convenient for drinking. Of course, the purified water flowing through the heating mechanism 290 can also be controlled by the valve assembly 230 to be delivered to the cup body assembly 210 for preparing beverages. For example, the purified water flowing through the heating mechanism 290 is boiled water, and the cup body assembly 210 can be used to brew it. Tea.

It can be understood that, if the purified water flowing through the heating mechanism 290 comes from the heat preservation container 220, since the purified water in the heat preservation container 220 itself has a relatively high temperature, it can be quickly heated to a higher temperature by the heating mechanism 290, Therefore, its flow rate can be faster. However, if the purified water flowing through the heating mechanism 290 comes from the purified water tank 204, since the temperature of the purified water in the purified water tank 204 is basically close to the room temperature, it takes a long time for the purified water to be heated to the required temperature by the heating mechanism 290. Therefore, its flow rate needs to be slower. Therefore, according to the above requirements, the water pumping rate of the second water pump 280 can be set to be greater than the water pumping rate of the first water pump 250, so as to meet the above-mentioned requirements of the flow rate.

Optionally, in this embodiment, the first water pump 250 and the second water pump 280 are both diaphragm pumps, which can better avoid leakage of water flow.

In this embodiment, the filter assembly 203 includes a pre-composite filter element, an RO reverse osmosis filter element, and a rear-mounted activated carbon filter element. That is, after the raw water is filtered by the pre-composite filter element, the RO reverse osmosis filter element and the rear activated carbon filter element in sequence, purified water is formed, which is transported to the water purification tank 204 . It can be understood that, in another feasible embodiment, the composition of the filter element of the filter assembly is not limited to this, and other filter elements that meet the filtration requirements can also be used. on three filters.

In this embodiment, the beverage machine further includes a casing 202, the casing 202 has an inner cavity, and the water purification mechanism, the heating mechanism 290, the heat preservation container 220, the water pump assembly and the valve assembly 230 are all located in the inner cavity of the casing 202 to protect the The water mechanism, the heating mechanism 290, the heat preservation container 220, the water pump assembly and the valve assembly 230 are protected from damage by the external environment. In addition, the water purification mechanism, the heating mechanism 290, the heat preservation container 220, the water pump assembly and the valve assembly 230 are arranged in the inner cavity of the housing 202, which can also improve the cleanliness of the appearance of the beverage machine.

The housing 202 includes a front panel 2022 having a recessed area 2023 on the outer surface thereof. The beverage handling mechanism is located on the outer surface of the recessed area 2023 of the front panel 2022. The concave area 2023 is concave inward, that is, the concave area 2023 is concave in the direction of the inner cavity of the casing 202 . The recessed area 2023 is recessed inward, and the beverage processing mechanism is located on the outer surface of the recessed area 2023 of the front panel 2022, thereby reducing the overall volume of the beverage machine, reducing the occupied space, and meeting the miniaturization requirements of the beverage machine.

Of course, it can be understood that the recessed area 2023 of the front panel 2022 is recessed inward, occupying part of the inner cavity of the casing 202 , so it is necessary to reasonably set the relative positional relationship of the structures disposed in the inner cavity of the casing 202 .

Specifically, in this embodiment, the heating mechanism 290 is located on the inner side of the front panel 2022, and is disposed adjacent to the front panel 2022; thus, the distance between the heating unit and the beverage processing mechanism is reduced, so that the distance between the heating unit and the beverage processing mechanism is reduced. The length of the connecting pipe between them is small, on the one hand, the conveying distance of the heated purified water is shorter, so that the temperature of the purified water conveyed to the beverage processing mechanism can be better guaranteed; The connecting pipes between the processing mechanisms take up less space.

Further, in this embodiment, the thermal insulation container 220 is located on the inner side of the front panel 2022, and is disposed adjacent to the front panel 2022, thereby reducing the distance between the thermal insulation container 220 and the second water pump 280, so that the thermal insulation container 220 is connected to the second water pump 280. The length of the connecting pipes between the water pumps 280 is small, so that on the one hand, the distance of the heat preservation water pumped out of the heat preservation container 220 is conveyed, so that the heat loss of the heat preservation water during the conveying process is small; The connecting pipe between the water pump 280 and the heat preservation container 220 occupies less space, which can better meet the requirement of miniaturization of the beverage machine.

Further, in this embodiment, the housing 202 further includes a first side panel 2024 adjacent to the front panel 2022, the first water pump 250 is located inside the first side panel 2024, and is connected with the second water pump 280 and the first side panel 2024 They are arranged adjacent to each other, so that the distance between the first water pump 250 and the heating mechanism 290 is relatively short, and the length of the connecting pipe between the first water pump 250 and the heating mechanism 290 is reduced.

Further, in this embodiment, the water purification tank 204 is located inside the front panel 2022 and is disposed adjacent to the front panel 2022 . Therefore, the distance between the first water pump 250 and the clean water tank 204 is reduced. On the one hand, the length of the connecting pipe between the first water pump 250 and the clean water tank 204 can be made smaller, so that the connecting pipe between the first water pump 250 and the clean water tank 204 occupies less space, and the first water pump 250 can be effectively avoided. The connecting pipe between the water pump 250 and the clean water tank 204 is easy to bend due to its long length.

Further, in this embodiment, the heating mechanism 290 , the heat preservation container 220 and the water pump assembly are all located on the bottom side of the water purification tank 204 . On the one hand, the clean water tank 204 is located on the upper side, which is convenient for draining the clean water in the clean water tank 204 to the heating mechanism 290, reducing the burden on the first water pump 250 and improving the efficiency and service life of the first water pump 250; On the one hand, the heating mechanism 290 , the heat preservation container 220 and the water pump assembly are all located on the bottom side of the water purification tank 204 , so that the beverage machine can be placed in a direction perpendicular to the depth of the water purification tank 204 under the premise of ensuring the volume of the water purification tank 204 . On the other hand, the clean water tank 204 is located on the upper side, which is convenient for cleaning the clean water tank 204 .

In this embodiment, the beverage machine further includes a bottom plate assembly 205 and an original water tank installation position 2051 . The raw water tank installation position 2051 and the cover 202 are both fixed on the bottom plate assembly 205 . The raw water tank installation position 2051 is disposed adjacent to the casing 202 , and the raw water tank installation position 2051 is located on the side of the casing 202 away from the front panel 2022 . That is, the original water tank installation position 2051 is located at the rear end of the beverage machine. It is convenient to install and remove the original water tank.

Further, in this embodiment, along the arrangement direction of the original water tank installation position 2051 and the cover 202 on the bottom plate assembly 205, that is, the MM direction in FIG. 1, the filter assembly 203 is located at the clean water tank 204 and the original water tank installation position 2051 between. Therefore, the raw water tank, the filter assembly 203 and the clean water tank 204 arranged on the raw water tank installation position 2051 are arranged in sequence, and the clean water obtained after the raw water in the raw water tank is filtered by the filter assembly 203 is stored in the clean water tank 204. It is basically the same, so that the filtration process is smoother, and the connecting pipes used to connect the raw water tank and the filter assembly 203 and the filter assembly 203 and the clean water tank 204 are shorter.

In this embodiment, the original water tank installation position 2051 is detachably and fixedly connected to the bottom plate assembly 205 . It can be understood that, in another feasible embodiment, the raw water tank installation position 2051 and the bottom plate assembly 205 may also be fixedly connected, or integrally formed.

Specifically, in this embodiment, as shown in FIGS. 6 to 13 , the valve assembly 230 includes a main body 110 , a first electromagnetic drainage unit, and a second electromagnetic drainage unit. Specifically, referring to FIGS. 8 to 12 , the main body 110 has a first cavity 111 , a second cavity 112 , a first communication channel 114 connecting the first cavity 111 and the second cavity 112 , and the first cavity 111 . The connected water inlet 116 , the first water outlet 117 communicated with the first cavity 111 , the second water outlet 118 communicated with the second cavity 112 , and the third water outlet 119 communicated with the second cavity 112 .

The first electromagnetic drainage unit can be selectively switched between the first state and the second state to selectively block the first communication channel 114 and the first water outlet 117 . When the first electromagnetic drainage unit is in the first state, the first communication channel 114 is blocked, and the first water outlet 117 is connected to the first cavity 111, so the fluid entering the first cavity 111 from the water inlet 116 is discharged from the first water outlet. 117 flows out, see Figure 8. When the first electromagnetic drainage unit is in the second state, the first water outlet 117 is blocked, and the first cavity 111 and the second cavity 112 are connected through the first communication channel 114 , so the water inlet 116 enters the first cavity 111 . The fluid flows from the first communication channel 114 to the second cavity 112 , see FIGS. 12 and 13 .

The second electromagnetic drainage unit can be selectively switched between the third state and the fourth state to selectively block the second communication channel 115 and the second water outlet 118 . When the second electromagnetic drainage unit is in the third state, the second communication channel 115 is blocked, and the second water outlet 118 is connected to the second cavity 112 , so the fluid flowing into the second cavity 112 flows out from the second water outlet 118 . Figure 21. When the second electromagnetic drainage unit is in the fourth state, the second water outlet 118 is blocked, and the second cavity 112 and the third water outlet 119 are connected through the second communication channel 115 , so the fluid flowing into the second cavity 112 passes through the second The communication channel 115 flows to the third water outlet 119 , and then flows out from the third water outlet 119 , see FIG. 13 .

It can be understood that the first cavity 111 and the second cavity 112 communicate with each other, so when the first communication channel 114 is not blocked, the fluid entering from the water inlet 116 can flow into the first cavity 111 and the second cavity in sequence. Two cavities 112 . When the first electromagnetic drainage unit is in the first state, the fluid flows out from the first water outlet 117 ; when the first electromagnetic drainage unit is in the second state, and the second electromagnetic drainage unit is in the third state, the fluid flows out of the second water outlet 118 Outflow; when the first electromagnetic drainage unit is in the second state, and the second electromagnetic drainage unit is in the fourth state, the fluid flows out from the third water outlet 119 .

Therefore, the valve assembly 230 can adjust the state of the first electromagnetic drainage unit and the second electromagnetic drainage unit, so that the liquid entering from the water inlet 116 flows from one of the first water outlet 117 , the second water outlet 118 and the third water outlet 119 . Outflow, that is, the liquid can flow out from one of at least three water outlets to achieve the effect of one inlet and multiple outlets. Therefore, one valve assembly 230 can meet the requirement of a complex water circuit with one inlet and multiple outlets, avoid the phenomenon of a plurality of valve assemblies 230 being connected in series or in parallel, occupying less space and lowering the cost.

In this embodiment, the first water outlet 117 is communicated with the water outlet 201 , that is, the first water outlet 117 is a water intake outlet. The second water outlet 118 communicates with the heat preservation container 210 . The third water outlet 119 communicates with the cup assembly 210 . Therefore, when water enters the water inlet 116 and the first electromagnetic drainage unit is in the first state, the first water outlet 117 discharges water. When water enters the water inlet 116 , the first electromagnetic drainage unit is in the second state, and the second electromagnetic drainage unit is in the third state, water flows out of the second water outlet 118 , and the water flowing out of the second water outlet 118 flows into the heat preservation container 210 . When water enters the water inlet 116 , the first electromagnetic drainage unit is in the second state, and the second electromagnetic drainage unit is in the fourth state, the third water outlet 119 discharges water, and the water flowing out of the third water outlet 119 flows into the cup assembly 210 .

Therefore, if there is a need for direct drinking, the first electromagnetic drainage unit can be controlled to be in the first state, so that the water entering from the water inlet 116 flows out from the first water outlet 117; if there is a need to process it into drinks such as tea or juice , the first electromagnetic drainage unit can be controlled to be in the second state, and the second electromagnetic drainage unit is in the fourth state, so that the water entering from the water inlet 116 flows out through the third water outlet 119; if there is no direct drinking demand, also There is no need to process beverages such as tea or fruit juice, and when only the heated water needs to be kept warm and stored, the first electromagnetic drainage unit can be controlled to be in the second state, and the second electromagnetic drainage unit is in the third state, so that the The water entering from the water inlet 116 flows out through the second water outlet 118 and flows into the thermal insulation container 210 for thermal insulation storage. The beverage machine provided in this embodiment uses the valve assembly described above, in combination with the cup body assembly, the water intake and the heat preservation container, so that the beverage machine can provide purified water and various liquids for beverages, and can quickly provide high-temperature water. Save time for users to connect hot water or brew drinks.

Further, in this embodiment, the main body 110 also has a second communication channel 115 that communicates with the second cavity 112 . The third water outlet 119 communicates with the second cavity 112 through the second communication channel 115 . Therefore, when the second electromagnetic drainage unit is in the fourth state, the second water outlet 118 is blocked, and the second cavity 112 and the third water outlet 119 are connected through the second communication channel 115, so the fluid flowing into the second cavity 112 passes through The second communication channel 115 flows to the third water outlet 119 , and then flows out from the third water outlet 119 , see FIG. 13 . When the second electromagnetic drainage unit is in the third state, the second communication channel 115 is blocked, so that the second water outlet 118 and the second cavity 112 are connected, so the fluid flowing into the second cavity 112 is discharged from the second water outlet 118 flows out, see FIG. 12 .

Further, in this embodiment, the main body 110 further has a third cavity 113 . The third cavity 113 is communicated with the second cavity 112 through the second communication channel 115 , and the third water outlet 119 is directly communicated with the third cavity 113 . Therefore, when the second electromagnetic drainage unit is in the fourth state, the second water outlet 118 is blocked, and the second cavity 112 and the third cavity 113 are connected through the second communication channel 115, so the fluid flowing into the second cavity 112 passes through The second communication channel 115 flows to the third cavity 113 , and then flows out through the third water outlet 119 , see FIG. 13 .

7 and 8 , in this embodiment, the main body 110 includes an upper valve body 30 , a lower valve body 40 fixedly connected with the upper valve body 30 , and a valve body 40 disposed on the side of the lower valve body 40 away from the upper valve body 30 Support frame 50 . And the support frame 50 is fixedly connected with the lower valve body 40 . The water inlet 116, the first water outlet 117 and the second water outlet 118 are provided on the upper valve body, and the third water outlet 119 is provided on the lower valve body. Moreover, the liquid flowing in from the water inlet 116 can flow out from one of the first water outlet 117 , the second water outlet 118 and the third water outlet 119 , so that when the upper valve body 30 and the lower valve body 40 are fixedly connected, there is a Docking and/or docking of cavities. Therefore, when the upper valve body 30 and the lower valve body 40 are fixedly connected, a sealing structure needs to be arranged between the upper valve body 30 and the lower valve body 40 to prevent water from flowing out from the position where the upper valve body and the lower valve body meet. Specifically, in this embodiment, the sealing structure between the upper valve body 30 and the lower valve body 40 is a sealing ring 60 . Of course, the sizes of the sealing rings 60 at different positions can be set as required. Similarly, in this embodiment, a sealing ring 60 is also provided between the lower valve body 40 and the support frame 50 . Of course, if the main body is provided with an opening that communicates the cavity or the communication channel with the outside world, when the opening needs to be blocked, the opening should also be sealed. For example, seal 70 in FIG. 7 .

It can be understood that, in another feasible embodiment, the main body can also be divided into two halves, or be decomposed into several elements by other decomposition methods, so as to satisfy the requirements between the cavity, the circulation channel, the water inlet and the water outlet in this application. can be related to each other.

In this embodiment, the first electromagnetic drainage unit includes a first mover 131 , a first coil 133 sleeved on the first mover 131 , a coil 133 located in the first cavity 111 and fixedly connected to the first mover 131 . The first plug 135 and the first reset member 137; the first coil 133 is not energized, and the first mover 131 is reset under the action of the first reset member 137, so that the first water outlet 117 is sealed by the first plug 135 Blocked, that is, the first electromagnetic drainage unit is in the second state, see FIG. 12 . The first coil 133 is energized, and the first mover 131 moves to drive the first plug 135 to move, so that the first communication channel 114 is blocked by the first plug 135, that is, the first electromagnetic drainage unit is in the first state, refer to Figure 8.

Further, in this embodiment, referring to FIG. 8 , the first electromagnetic drainage unit further includes a first connecting member 139 movably penetrated through the first communication channel 114 . Both ends of the first connecting member 139 are fixedly connected to the first plug 135 and the first mover 131 respectively. In a direction perpendicular to the extending direction of the first communication channel 114 , the cross-sectional area of the first connecting member 139 is smaller than that of the first communication channel 114 . Therefore, when the first plug 135 does not block the first communication channel 114, the fluid in the first cavity 111 can flow to the second through the space between the first connecting member 139 and the side wall of the first communication channel 114 Cavity 112 .

It should be noted that the first coil 133 needs to be isolated from water, so the first coil 133 cannot be directly located in the first cavity 111 . In this embodiment, the first coil 133 is located outside the first cavity 111 , and correspondingly, the first mover 131 is also located outside the first cavity 111 . By passing the first connecting member 139 connecting the first mover 131 and the first plug 135 into the first communication channel 114 , that is, it is not necessary to provide another passing channel for the first connecting member 139 , so that the structure of the main body 110 is improved. Simpler. In addition, in this embodiment, the first connecting member 139 is spaced from the side wall of the first communication channel 114, which can also avoid friction between the first connecting member 139 and the side wall of the first communication channel 114, so that the first mover 131 can drive the first plug 135 to move more smoothly.

In this embodiment, the first mover 131 and the first connecting member 139 are integrally formed. Of course, in another feasible embodiment, the first mover and the first connecting member may also be provided separately, and the first mover and the first connecting member are fixedly connected. Alternatively, the first mover and the first connector may be connected through other connecting structures, so that the first mover and the first connector can be linked together.

In this embodiment, the main body 110 also has a first accommodating space 1112, and the first accommodating space 1112 is sealed with the first communication channel 114, that is, the liquid in the first communication channel 114 will not flow to the first accommodating space within 1112. The first mover 131 is partially inserted into the first accommodating space 1112 , the first coil 133 is disposed in the first accommodating space 1112 , and the first coil 133 is sleeved on the first mover 131 . On the one hand, the first coil 133 can be energized to drive the first mover 131 to move; on the other hand, it can also prevent the fluid from flowing into the first accommodating space 1112 and causing the first coil 133 to short-circuit. It can be understood that the first accommodating space 1112 is located on the side of the first communication channel 114 away from the first cavity 111 .

In this embodiment, the first reset member 137 is an elastic member disposed in the first accommodating space 1112 . Specifically, one end of the first reset member 137 is in contact with the main body 110 , and the other end is in contact with the first mover 131 . The first mover 131 moves upward in the view direction shown in FIG. 8 under the elastic force of the first reset member 137 until the first plug 135 blocks the first water outlet 117 , so that the first electromagnetic drainage unit is in the second state. Correspondingly, after the first coil 133 is energized, under the action of the magnetic force of the magnetic field generated by the first coil 133, the first mover 131 overcomes the elastic force of the first reset member 137 and moves downward along the view direction shown in The plug 135 blocks the first communication channel 114, so that the first electromagnetic drainage unit is in the first state.

More specifically, in this embodiment, the first accommodating space 1112 is surrounded by the support frame 50 . It can be understood that, in another feasible embodiment, the first accommodating space may also be provided on the upper valve body or the lower valve body. Of course, in another feasible embodiment, if the structure of the main body is in two halves, or is decomposed into several elements by other decomposition methods, a first accommodating space is provided on one or several elements constituting the main body, And it only needs to meet the requirements of the positions and activities of the structures such as the first mover and the first coil.

In this embodiment, a frame 80 is also fixed in the first accommodating space 1112 , and the frame 80 is sleeved on the first mover 131 , and the first coil 133 is sleeved on the frame 80 . On the one hand, the first mover 131 can be inserted into the first accommodating space 1112 more stably to avoid the tilt of the first mover 131; A coil 133 .

Specifically, one end of the first reset member 137 is in contact with the frame 80 , and the frame 80 is fixed in the first accommodating space 1112 , so as to realize the abutment of the first reset member 137 and the support frame 50 , that is, to realize the first reset member 137 Contact with the support frame 50 .

In this embodiment, the support frame 50 is further provided with a pressing plate 90 for covering the first accommodating space 1112 . On the one hand, it is convenient for the sealing connection between the support frame 40 and the lower valve body 40, and on the other hand, it can effectively prevent the structures such as the first coil other than the first mover 131 in the first accommodating space 1112 from passing from the first accommodating space. 1112 slide out.

Of course, it can be understood that, in another feasible embodiment, the first coil is not energized, the first mover is reset under the action of the first reset member, and the first communication channel can also be blocked by the first plug, That is, the first electromagnetic drainage unit is in the first state at this time. Correspondingly, the first coil is energized, and the first mover moves to drive the first plug to move, so that the first water outlet is blocked by the first plug, that is, the first electromagnetic drainage unit is in the second state. Of course, compared with the valve assembly 230, the position of the first reset member needs to be adjusted at this time, so as to change the direction of the reset force of the first reset member acting on the first mover.

In addition, it can be understood that, in another feasible embodiment, the first electromagnetic drainage unit is not limited to this, and the first electromagnetic drainage unit can be switched between the first state and the second state.

In this embodiment, the second electromagnetic drainage unit includes a second mover 151 , a second coil 153 sleeved on the second mover 151 , a coil located in the second cavity 112 and fixedly connected to the second mover 151 . The second plug 155 and the second reset member 157 ; the second coil 153 is not energized, and the second mover 151 is reset under the action of the second reset member 157 , so that the second water outlet 118 is blocked by the second plug 155 , that is, the second electromagnetic drainage unit is in the fourth state, see FIG. 13 . The second coil 153 is energized, and the second mover 151 moves to drive the second plug 155 to move, so that the second communication channel 115 is blocked by the second plug 155, that is, the second electromagnetic drainage unit is in the third state, refer to Figure 12.

In this embodiment, the structure of the second electromagnetic drainage unit is exactly the same as that of the first electromagnetic drainage unit, which will not be repeated here. Of course, it can be understood that, in another feasible embodiment, the structures of the second electromagnetic drainage unit and the first electromagnetic drainage unit may also be different, as long as their respective drainage functions can be achieved.

Of course, in another feasible embodiment, the second coil is not energized, the second mover is reset under the action of the second reset member, and the second communication channel can also be blocked by the second plug, that is, the second electromagnetic drainage The unit is in the third state. Correspondingly, when the second coil is energized, the second mover moves to drive the second plug to move, so that the second water outlet is blocked by the second plug, that is, the second electromagnetic drainage unit is in the fourth state.

In this embodiment, referring to FIGS. 8 to 10 , the main body 110 further includes an intermediate cavity 1111 , and the first cavity 111 , the intermediate cavity 1111 and the second cavity 112 are connected in sequence. The first cavity 111 and the intermediate cavity 1111 communicate with each other through the first communication channel 114 . The fluid in the first cavity 111 first flows to the intermediate cavity 1111 through the first communication channel 114 , and then flows from the intermediate cavity 1111 to the second cavity 112 . Due to the arrangement of the first connecting member 139 , the structure of the first communication channel 114 can only extend in a straight line, or has a small degree of bending or bending, so that the first connecting member 139 can move in the first communication channel 114 . Therefore, if the second cavity 112 is directly connected to the first cavity 111 through the first communication channel 114 , the relative positional relationship between the first cavity 111 and the second cavity 112 is limited. In the present application, the position of the second cavity 112 can be freely selected as required by the arrangement of the intermediate cavity 1111 , so that the second water outlet 118 can be freely arranged at the required position.

More specifically, the intermediate cavity 1111 communicates with the second cavity 112 through an intermediate communication channel. In addition, in this embodiment, the middle cavity 1111 is located on the lower valve body 40 , and the second cavity 112 is located on the upper valve body 30 . Therefore, the intermediate communication channel includes the first section 102 a provided on the lower valve body 40 and the second end 102 b provided on the upper valve body 30 . The first section 102a is butted with the middle cavity 1111, and the second section 102b is butted with the second cavity 112, so that the liquid in the middle cavity 1111 can be communicated through the middle of the first section 102a and the second section 102b. The channel flows into the second cavity 112 .

In this embodiment, the valve assembly 230 further includes a first blocking member 10 disposed in the first cavity 111 and partially located on the side of the first plug 135 close to the water inlet 116 to prevent the water from flowing from the water inlet 116 to the first stopper 116 . The fluid in the cavity 111 directly impacts the first plug 135, thereby preventing the first plug 135 from being skewed or deformed due to the impact of the fluid, so as to ensure the blocking of the first electromagnetic drainage unit in the first state and the second state respectively. Effect.

In this embodiment, the first blocking member 10 extends to at least partially surround the first plug 135 . Of course, it can be understood that, in another feasible embodiment, the first baffle 10 may only be located on the side of the first plug 135 close to the water inlet 116 .

Similarly, in this embodiment, the valve assembly 230 further includes a second blocking member 20 disposed in the second cavity 112 to block the fluid flowing into the second cavity 112 from directly impacting the second plug 155, thereby preventing the The second plug 155 is skewed or deformed due to the impact of the fluid, so as to ensure the blocking effect of the second electromagnetic drainage unit in the second state and the third state, respectively.

In this embodiment, the second blocking member 20 is also at least partially disposed around the second plug 155 . Similarly, in another feasible embodiment, the second flow blocking member 20 is not limited to being disposed around the second plug 155, and can block the fluid flowing into the second cavity 112 from directly impacting the second plug 155.

Specifically, in this embodiment, the beverage machine 200 further includes a heat preservation container 220 and a cup body 212 . The first water outlet 117 is a water intake outlet, the second water outlet 118 is communicated with the heat preservation container 220 , and the third water outlet 119 is communicated with the cup body 212 . Therefore, when water enters the water inlet 116 and the first electromagnetic drainage unit is in the first state, the first water outlet 117 discharges water. When water enters the water inlet 116 , the first electromagnetic drainage unit is in the second state, and the second electromagnetic drainage unit is in the third state, the water flows out of the second water outlet 118 , and the water flowing out of the second water outlet 118 flows into the heat preservation container 220 . When the water inlet 116 enters the water, the first electromagnetic drainage unit is in the second state, and the second electromagnetic drainage unit is in the fourth state, the third water outlet 119 discharges water, and the water flowing out of the third water outlet 119 flows into the cup body 212 .

Therefore, if there is a need for direct drinking, the first electromagnetic drainage unit can be controlled to be in the first state, so that the water entering from the water inlet 116 flows out from the first water outlet 117; if there is a need to process it into drinks such as tea or juice , the first electromagnetic drainage unit can be controlled to be in the second state, and the second electromagnetic drainage unit is in the fourth state, so that the water entering from the water inlet 116 flows out through the third water outlet 119; if there is no direct drinking demand, also There is no need to process beverages such as tea or fruit juice, and when only the heated water needs to be kept warm and stored, the first electromagnetic drainage unit can be controlled to be in the second state, and the second electromagnetic drainage unit is in the third state, so that the The water entering from the water inlet 116 flows out through the second water outlet 118 and flows into the thermal insulation container 220 for thermal storage. The beverage machine provided in this embodiment uses the valve assembly described above, in combination with the cup body assembly, the water intake outlet and the heat preservation container, so that the beverage machine can provide purified water and various liquids for beverages, and can quickly provide higher temperature water. Save time for users to connect hot water or brew drinks.

Of course, it can be understood that, in another feasible embodiment, the corresponding relationship between the heat insulating container and the cup body assembly and the water outlet can be readjusted according to the positions of the heat insulating container and the cup body assembly respectively relative to the valve assembly.

As shown in FIGS. 1 , 14 to 23 , the beverage processing mechanism further includes a water outlet seat 400 disposed on the bottom side of the cup assembly. Specifically, the water outlet seat 400 includes a bottom frame 410 , a water outlet nozzle 430 , a top piece 450 and an electric drive assembly 470 . Wherein, the water outlet 430 is movably arranged on the bottom frame 410 . The spout 430 moves to switch between the first position and the second position. The top piece 450 has a first connecting portion 451 rotatably connected to the bottom frame 410 , a second connecting portion 453 that is offset from the first connecting portion 451 , and a top portion 455 that is offset from the first connecting portion 451 . The top piece 450 is rotatable to switch the top 455 between a jacked-up position and a retracted position. When the top 455 is switched from the falling position to the jacking position, the water outlet 430 is jacked up to the first position, the top 455 is in the jacking position and the water outlet 430 is in the first position. Refer to FIGS. 19 and 23 for structural diagrams. When the top 455 is switched from the jacking position to the falling position, the water outlet 430 can be forced to fall back to the second position. The top 455 is in the falling position and the water outlet 430 is in the second position. Refer to FIG. 15 and FIG. 22 for structural diagrams. The electric drive assembly 470 is used to drive the second connecting portion 453 of the top piece 450 to move so that the top piece 450 is rotated until the top 455 is in the jacked position.

The bottom of the cup assembly 210 is provided with a water outlet 211 that is butted with the water outlet 430 . A valve core 2125 is provided at the water outlet 211 . Wherein, when the water outlet 430 moves from the second position to the first position, the water outlet 430 drives the valve core 2125 to move in the first direction. After the valve core 2125 is separated from the driving force of the water outlet 430, it can automatically move in the second direction. The first direction refers to a direction extending along the water outlet 211 and pointing to the inner cavity of the cup assembly 210 . The second direction refers to a direction extending along the water outlet 211 and away from the inner cavity of the cup assembly 210 .

Specifically, in this embodiment, the water outlet 430 is driven to move from the first position to the second position during the movement in the direction extending along the water outlet 211 and away from the inner cavity of the cup assembly 210 . When the water outlet 430 is in the first position, the valve core 2125 remains open. When the water outlet 430 is in the second position, the valve core 2125 remains in an automatically closed state.

The setting of the above-mentioned water outlet seat 400 is driven by the electric drive assembly 470 to drive the top piece 450 to rotate, thereby making the water outlet nozzle 430 switch between the first position and the second position, so that the valve core at the water outlet of the cup assembly is close to or away from The inner cavity of the cup assembly moves, thereby realizing the opening or closing of the valve core, that is, the beverage machine can continue to discharge water without continuously operating the operation button.

Of course, in another feasible embodiment, if the valve core 2125 is automatically kept open without the action of the water outlet 430, then when the water outlet 430 is in the first position, the valve core 2125 remains closed. When the water outlet 430 is in the second position, the valve core 2125 remains in an automatically open state.

It should be noted that, in another feasible embodiment, when the water outlet moves from the second position to the first position, the valve core can also be driven to move in the opposite direction, that is, the valve core can be driven to move along the extending direction of the water outlet and away from the water outlet. The direction of the inner cavity of the beverage container moves. Correspondingly, after the valve core is separated from the driving force of the water outlet, it can automatically move in a direction along the extending direction of the water outlet and toward the inner cavity of the beverage container. Specifically, a transmission mechanism such as a rack and pinion transmission can be used, so that when the water outlet nozzle drives the valve core to move, the water outlet nozzle and the valve core move in opposite directions.

Specifically, in this embodiment, the first connecting portion 451 and the second connecting portion 453 are located at opposite ends of the top member 450 respectively, and the top portion 455 is located between the first connecting portion 451 and the second connecting portion 453 . It can be understood that, in another feasible embodiment, the first connecting portion and the second connecting portion are not limited to be located at two ends of the top piece, respectively. Likewise, the top is not limited to being located between the first connecting portion and the second connecting portion. The top piece and the bottom frame can be connected in rotation through the first connecting part, and the second connecting part of the top piece can be driven by the electric drive assembly to move so that the top piece is rotated until the top is in the jacked-up position.

In this embodiment, by rotating the top piece 450 and the bottom frame 410, the top piece 450 can be effectively prevented from shifting, so that the water outlet 430 can be driven to switch between the first position and the second position more stably. At the same time, the top 455 can be switched to the jacking position and the falling position more accurately, so that when the top 455 is in the jacking position, the water outlet 430 can be more accurately jacked up to the first position, and can also be positioned at the top 455. In the falling position, the water outlet 430 can be forced to fall back to the second position more accurately.

Of course, it can be understood that the beverage machine with the water outlet seat 400 has a control system, and the control system controls the operation of the electric drive assembly 470 after receiving the water outlet instruction.

It should be noted that, referring to FIG. 21 , the water outlet 430 has a drainage channel 431 with open ends at both ends. Two ends of the drainage channel 431 are the first end 1311 and the fourth end 1313 respectively. The water outlet 430 is used for docking with the cup assembly on the beverage machine, and the beverage in the cup assembly flows out from the water outlet 430 . Specifically, the first end 1311 of the drainage channel 431 is butted with the cup assembly. The beverage in the cup assembly flows into the drainage channel 431 from the first end 1311 of the drainage channel 431 and flows out from the fourth end 1313 of the drainage channel 431 .

In addition, it should be noted that, in this embodiment, when the water outlet 430 moves from the second position to the first position, the valve core can be pushed to move, thereby changing the opening and closing state of the valve core. Specifically, in this embodiment, a push portion 433 is provided on the inner side wall of the drainage channel 431 of the water outlet 430. During the movement of the water outlet 430 from the second position to the first position, the push portion 433 is in contact with the valve core. to push the spool to move.

Optionally, in this embodiment, the push portion 433 is completely located in the drainage channel 431 of the water outlet. Therefore, when the beverage in the cup assembly flows through the drainage channel 431 of the water outlet 430, the push portion 433 can play a role of drainage.

Further, the end of the push portion 433 for abutting with the valve core is spaced from the first end 1311 of the drainage channel 431 , that is, the end of the push portion 433 close to the first end 1311 of the drainage channel 431 and the first end 1311 of the drainage channel 431 are spaced apart. One end 1311 is spaced. On the one hand, it can make the liquid flow out more smoothly from the fourth end 1313 of the drainage channel 431; The structure of the electric drive components, etc., is affected by moisture, which affects the operation of the electric drive components, etc., and also prevents the beverage from adhering to the top piece and the bottom frame and other structures, which affects the cleaning of the top piece and the bottom frame, and avoids the breeding of bacteria.

In addition, in this embodiment, the drainage channel 431 is provided with two push portions 433 spaced along the circumferential direction of the drainage channel 431 . Therefore, the hydraulic pressure of the beverage flowing into the drainage channel 431 of the water outlet 430 can be balanced to a certain extent, so that the beverage can flow out from the fourth end 1313 of the drainage channel 431 more smoothly.

In this embodiment, the two push parts 433 have the same structure and the same size, and are arranged relative to the axis of the drainage channel 431, so that when the valve core is pushed to move, the axial force of the valve core can be balanced, that is, the single-sided force of the valve core can be avoided. The phenomenon of lateral force concentration. It can be understood that, in the other two possible embodiments, the number of pushing parts in the drainage channel is not limited to two. In addition, the sizes and shapes of different push portions may be different, and the intervals between adjacent push portions may be the same or different.

Of course, in another feasible embodiment, the push portion may also be provided on the outer side or end portion of the water outlet, and it only needs to be able to push the valve core to move. Alternatively, the movement of the valve core can also be pushed directly through the end of the water outlet.

Of course, in another feasible embodiment, the valve core can also be driven to move in the opposite direction through the movement of the water outlet 430, for example, by arranging a gear transmission mechanism between the water outlet and the valve core.

In this embodiment, the movement of the valve core at the water outlet of the cup body assembly is directly controlled by the movement of the water outlet 430 , avoiding the use of other components, thereby making the structure of the water outlet seat 400 simpler.

Specifically in this embodiment, the first connecting portion 451 and the second connecting portion 453 of the top member 450 are relatively fixed. The axis of rotation of the first connecting portion 451 of the top piece 450 relative to the bottom frame 410 is the first axis a, and the electric drive assembly 470 drives the second connecting portion 453 of the top piece 450 to rotate around the first axis a, so that the top piece 450 rotates around the first axis a. An axis a rotates.

More specifically, in this embodiment, both the first connecting portion 451 and the second connecting portion 453 of the top member 450 are tilted relative to the top portion 455 . Of course, in another feasible embodiment, the first connecting portion 451 and the second connecting portion 453 of the top piece 450 are not limited to be tilted relative to the top portion 455 . The structure of the top piece 450 can be in any regular or irregular shape, so as to ensure that the electric drive assembly 470 can drive the second connecting portion 453 to move, so that the top piece 450 can be rotated.

Of course, in another feasible embodiment, if the first connecting part and the second connecting part of the top piece are relatively unfixed, the way that the second connecting part of the top piece moves under the driving of the electric drive assembly is no longer around the first connecting part. Rotation of an axis.

In this embodiment, the electric drive assembly 470 includes a rotatable rotating member 471 disposed on the bottom frame 410 and a motor 473 for driving the rotating member 471 to rotate. The rotating member 471 rotates to drive the second connecting portion 453 of the top member 450 to move, thereby driving the top member 450 to rotate until the top portion 455 is in the jacked-up position.

Specifically, the rotating member 471 abuts against the second connecting portion 453 of the top member 450 . The surface of the rotating member 471 abutting against the top member 450 has a protrusion 4711 . The rotation of the rotating member 471 can make the top end of the protrusion 4711 abut or disengage from the second connecting portion 453 of the top member 450 . It can be understood that when the top end of the protrusion 4711 abuts against the second connecting portion 453 of the top piece 450, the second connecting portion 453 of the top piece 450 reaches the highest position to be lifted, so that the top piece 450 is kept in the jacked-up position. Location. Correspondingly, when the second connecting portion 453 of the top piece 450 is disengaged from the top end of the protrusion 4711, the top piece 450 can be switched from the jacked-up position to the fall-down position under the action of an external force.

In this embodiment, in the surface of the rotating member 471 abutting against the top member 450 , the part without the protrusion 4711 is a depression 4713 ; The rotating member 471 is rotated until the protrusion 4711 abuts or disengages from the abutting protrusion 454 . After the contact protrusion 454 is separated from the protrusion 4711, the contact protrusion 454 can be forced to move toward the depression 4713 until the top 455 is at the falling position. Specifically, the contact protrusion 454 can be forced to move to the depression 4713. bottom end abuts. Therefore, the top end of the protrusion 4711 and the bottom end of the concave 4713 can alternately abut against the abutting protrusion 454, so that the top part 455 can be located at the jacking position or the falling position more accurately. Correspondingly, the driven water nozzle 430 can be more accurately Precisely located in the first position or the second position, the accuracy of the movement of the water outlet 430 is ensured, so that the valve core can be better kept in an open or closed state.

In this embodiment, the rotating member 471 is provided with two protrusions 4711 and two depressions 4713 , and the protrusions 4711 and the depressions 4713 are arranged annularly at intervals around the rotation axis of the rotating member 471 . Therefore, during the rotating process of the rotating member 471, the top can be continuously switched between the jacking position and the falling position.

In this embodiment, the center of the protrusion 4711 and the vertical line of the rotation axis of the rotating member 471 are perpendicular to the vertical line of the adjacent recess 4713 and the rotation axis of the rotating member 471 . Therefore, every time the rotating member rotates 90°, the top can be switched from the jacking position to the falling position, or from the falling position to the jacking position.

In this embodiment, a smooth transition between the protrusion 4711 and the depression 4713 enables the top to switch between the jacked-up position and the fall-back position more stably, thereby enabling the valve core to switch between opening and closing more smoothly.

Of course, it can be understood that, in another feasible embodiment, after the abutting protrusion is detached from the top end of the protrusion, the abutting protrusion 454 can be forced to move toward the recess 4713 until the top 455 is at the falling position, and the abutting protrusion 454 is in the falling position. The protruding portion can also only abut against the opposite two side walls of the adjacent two protuberances without abutting against the bottom ends of the recesses.

In this embodiment, when the rotating member 471 rotates within the preset path, the top end of the protrusion 4711 can be kept in contact with the top member 450, and the top portion 455 can be kept in the lifting position, so that the rotating member 471 can rotate to the preset path. In any position within, the top 455 can be kept in the jacked-up position, reducing the requirement for the rotation precision of the rotating member 471 .

Specifically, the top of the protrusion 4711 can be set as a plane, and when the top piece 450 abuts against the plane, the top 455 is kept in the jacked-up position. And/or, the surface of the second connecting portion 453 of the top piece 450 abutting against the top end of the protrusion 4711 is set to be a plane, and when the top end of the protrusion 4711 is in contact with the plane, the top portion 455 remains in the jacked position .

Of course, it can be understood that, in another feasible embodiment, the protrusions may also be provided on the surface of the second connecting portion of the top piece that abuts against the rotating piece. Through the rotation of the rotating member, the top end of the protrusion is abutted or disengaged from the rotating member, and the rotation of the rotating member can also drive the top of the top member to switch between the jacking position and the falling position. Further, abutting protrusions can also be provided on the adapter, and the abutting protrusions on the adapter can abut or abut the top ends of the protrusions on the second connecting portion of the top member through the rotation of the rotating member. disengaged, so that the rotation of the rotating member drives the top of the top member to switch between the jack-up position and the fall-back position.

In this application, the rotating member 471 is directly connected to the output shaft of the motor 473 , that is, the motor 473 directly drives the rotating member 471 to rotate. Of course, it can be understood that, in another feasible embodiment, a transmission mechanism may be additionally provided between the motor 473 and the rotating member 471 , that is, the motor 473 drives the rotating member 471 to rotate through the transmission mechanism.

In this embodiment, the rotation axis of the rotating member 471 is parallel to the moving direction of the water outlet 430 . It can be understood that, in another feasible embodiment, the rotation axis of the rotating member 471 and the moving direction of the water outlet 430 may not be parallel, as long as the second connecting portion 453 of the top member 450 can be driven to move.

In this embodiment, the surface of the rotating member 471 abutting against the second connecting portion 453 of the top member 450 is perpendicular to the rotation axis of the rotating member 471 . In another possible embodiment, the surface of the rotating member 471 that abuts against the second connecting portion 453 of the top member 450 may also be parallel to the rotation axis of the rotating member 471, or another regular or irregular surface of the rotating shaft, which can The second connecting portion 453 of the top piece 450 is driven to move so that the top portion 455 can be switched between the jacking position and the falling position.

In this embodiment, the rotating member 471 is cylindrical. It can be understood that, in another feasible embodiment, the rotating member 471 is not limited to being cylindrical, but can also be any other regular or irregular shape, and can be rotated to drive the second connecting portion 453 of the top member 450 to move. .

In this embodiment, the top 455 is provided with a via hole 4551 , and the water outlet 430 is penetrated through the via hole 4551 . A limiting member 435 is provided on the outer side wall of the water outlet 430 . When the top 455 is switched from the falling position to the jacking position, the top 455 is in contact with the limiting member 435 to drive the water outlet 430 to move from the second position to the first position. That is, the top 455 drives the water outlet 430 to move through the limiting member 435 . The water outlet 430 is disposed in the through hole 4551 , so that the water outlet 430 can occupy less space outside the chassis 410 , thereby reducing the volume of the water outlet 400 and meeting the miniaturization requirement of the water outlet 400 .

In addition, the water outlet 430 is penetrated in the through hole 4551, so that the limiter 435 is arranged on the outer wall of the water outlet 430 and the top 455 is abutted with the limiter 435, which facilitates the movement of the water outlet 430 and has a simple structure.

It can be understood that the top piece 450 is rotated to drive the water outlet 430 to move. During the rotation of the top piece 450, the included angle between the depth direction of the via hole 4551 and the moving direction of the water outlet nozzle 430 is constantly changing. Specifically, in this embodiment, the depth direction of the via hole 4551 is the extension direction of the inner wall of the via hole 4551 , that is, the P-P direction shown in FIG. 17 . When the top 455 of the top piece 450 is in the falling position, the depth direction of the via hole 15551 is the same as the moving direction of the water outlet 430 . When the top 455 of the top piece 450 is switched from the falling position to the jacking position, the top piece 450 rotates, so the inner wall of the through hole 4551 also rotates accordingly, so the depth direction of the through hole 4551 also rotates accordingly, and the moving direction of the water outlet 430 Therefore, the angle between the depth direction of the via hole 4551 and the moving direction of the water outlet nozzle 430 changes. Therefore, during the rotation of the top piece 450, the included angle between the depth direction of the via hole 4551 and the moving direction of the water outlet 430 is constantly changing. Further, with the rotation of the top piece 450, the inner wall of the via hole 4551 also rotates correspondingly, while the direction of the outer side wall of the water outlet 430 does not change. Therefore, with the rotation of the top piece 450, the angle between the inner wall of the via hole 4551 and the outer side wall of the water outlet 430 changes. Therefore, there needs to be a space between the water outlet 430 and the inner wall of the via hole 4551 for the relative change between the inner wall of the via hole 4551 and the outer side wall of the water outlet 430 . In other words, there is a space between the water outlet 430 and the inner wall of the through hole 4551 so that the top piece 450 can be rotated.

In this embodiment, the via hole 4551 is a waist-shaped hole. On the one hand, the change of the angle between the depth direction of the via hole 4551 and the moving direction of the water outlet 430 can be realized; on the other hand, it can also prevent the via hole 4551 from being large and the strength of the top piece 450 from being reduced; The shape of 4551 is regular and easy to process. Of course, in another feasible embodiment, the via hole is not limited to the waist-shaped hole, but can also be any other regular or irregular shape, which can realize the change of the angle between the depth direction of the via hole and the moving direction of the water outlet. That's it.

In this embodiment, two limiting members 435 are symmetrically arranged on the water outlet 430, so as to avoid the phenomenon that the water outlet 430 is inclined due to the limiting member 435 on one side, and also prevents the water outlet 430 from being prone to stress concentration on one side. damage. Of course, it can be understood that, in another feasible embodiment, the water outlet 430 is not limited to be provided with two limiting members 435 , and one or more than two limiting members 435 may also be provided. In addition, in this embodiment, the limiting member 435 is in the shape of a plate, and the direction of the plate is along the radial direction of the water outlet 430 . In another feasible embodiment, the shape of the limiting member 435 is not limited to a plate shape, and can also be any other regular or irregular shape, such as a ring shape, a cylindrical shape, and the like.

In this embodiment, the water outlet 430 is detachably disposed on the bottom frame 410 , so as to facilitate the cleaning of the water outlet 430 and the replacement of the water outlet 430 . In addition, when the water outlet seat is connected to the cup body assembly, the water outlet valve can be opened, so that the liquid in the cup body assembly can flow from the water outlet of the cup body assembly to the water outlet nozzle 430 . It can be understood that the water outlet 430 is installed on the bottom frame 410, and the water outlet is butted with the water outlet of the cup assembly. That is, the two ends of the water outlet 430 are the bottom frame 410 and the cup assembly respectively. Therefore, in order to realize the detachable connection between the water outlet 430 and the bottom frame 410, the water outlet base 400 must be detachably connected with the cup assembly. Thus, cleaning of the cup body assembly is facilitated. In addition, during the cleaning process of the cup body assembly, water can be prevented from accidentally splashing on the water outlet seat 400 and the operation of the electric drive components on the water outlet seat 400 and the like can be avoided, and water can also be prevented from accidentally splashing on the water outlet seat 400, resulting in the failure of the water outlet seat 400. The bottom frame 410 and the like breed bacteria in a humid environment, thereby ensuring that the water flowing out through the water outlet 400 is safer and more hygienic. The liquid in the cup assembly can flow directly into the drinking container after flowing out through the water outlet 430, that is, the entire circulation path of the beverage in the cup assembly can flow out only through the water outlet, and the water outlet is detachable, so as to realize all beverages Contact parts are washable, safe and hygienic.

Specifically, in this embodiment, the bottom frame 410 is provided with a cup body assembly mounting member 411 , and the cup body assembly mounting member 411 is provided with a mounting hole 413 matching the water outlet 430 . The water outlet 430 is detachably inserted into the installation hole 413 . More specifically, in this embodiment, the bottom frame 410 and the cup assembly mounting member 411 enclose an accommodating space, and the top member 450 and the rotating member 471 are all arranged in the accommodating space to protect the top member 450 and the rotating member 471 Not affected by the external environment.

More specifically, in this embodiment, the limiting member 435 is provided with a slip-off preventing portion 436 to prevent the water outlet 430 from slipping off the bottom frame 410 . After the water outlet 430 is inserted through the mounting hole 413 , the anti-dropping portion 436 is located between the mounting member 111 and the top member 450 , and the anti-dropping portion 436 is blocked by the mounting member 111 to prevent the water outlet 430 from falling out. It can be understood that when the water outlet 430 is inserted through the installation hole 413, the part of the water outlet 430 located around the anti-dropping portion 436 is slightly deformed, or the inner wall of the mounting hole 413 of the cup assembly mounting member 411 is slightly deformed, so as to prevent the water outlet 430 from being slightly deformed. The water outlet 430 can be inserted through the mounting hole 413 . When the water outlet 430 is pulled out from the installation hole 413 , the part of the water outlet 430 around the anti-dropping part 436 is slightly deformed or the inner wall of the mounting hole 413 of the cup assembly mounting member 411 is slightly deformed, so that the water outlet 430 is slightly deformed. It can be pulled out from the installation hole 413 , thereby realizing the detachable connection between the water outlet 430 and the bottom frame 410 .

Specifically, in this embodiment, two opposite outer surfaces of each limiting member 435 are respectively provided with a detachment prevention portion 436 , and the detachment prevention portion 436 is a convex point. It can be understood that, in another feasible embodiment, the number and shape of the anti-detachment parts 436 on each limiting member 435 are not limited to this, that is, each limiting member 435 may be provided with one or more than two The anti-dropping portion 436, the anti-dropping portion 436 may also have a regular or irregular shape such as a columnar shape.

In this embodiment, the second connecting portion 453 of the top member 450 is driven to rotate by the electric drive assembly 470 , so that the top portion 455 is switched from the falling position to the jacking position. Through the gravity of the top piece 450 and the pressure exerted by the water outlet 430 on the top piece 450 , the top piece 455 is switched from the jacking position to the falling position. Of course, in another optional embodiment, during the rotation of the second connecting portion, the top piece can also be switched from the jacking position to the falling position only under the action of its own gravity.

In addition, optionally, in another feasible embodiment, the second connection portion of the top member 450 may be driven to rotate by the electric drive assembly, so that the top portion can be switched between the falling position and the jacking position. For example, the second connecting part of the top piece is driven to reciprocate by the electric drive assembly, so that the top part is switched between the falling position and the jacking position.

In this embodiment, the bottom frame 410 is provided with a cup assembly identification mechanism 490 for identifying whether the cup assembly is installed in place. Specifically, the cup assembly identification mechanism 490 includes a movable trigger member provided on the bottom frame 410 and a trigger switch provided on the bottom frame 410 . When the cup body assembly is installed, the trigger member can be driven to move, and when the cup body assembly is installed in place, the cup body assembly drives the trigger member to move to the position where the trigger switch is triggered. After the trigger switch is triggered, the electric drive assembly 470 can run under the control of the control system, so as to avoid the phenomenon that the electric drive assembly 470 starts to run when the cup body assembly is not installed or the cup body assembly is not installed in place. The components are not installed in place, so that the beverage in the cup assembly cannot flow out along the drainage channel 431 of the water outlet 430 after flowing out, and it is also avoided that the beverage in the cup assembly flows to other positions of the water outlet 400 and causes the electric drive assembly 470 etc. Damaged by moisture.

It should be noted that, in another feasible embodiment, the structure of the cup body assembly identification mechanism 490 is not limited to this, and may also be a structure such as an infrared sensor, which can detect whether the cup body assembly is installed in place.

Optionally, in another feasible embodiment, a reset member is provided on the bottom frame, so that after the second connection portion of the top member is disengaged from the protrusion, the reset member drives the top member to rotate, so that the top is switched. to the fallback position. Specifically, the reset piece can drive the top piece to rotate after the second connecting part of the top piece is completely disengaged from the protrusion, or can drive the top piece after the second connecting part of the top piece is disengaged from the top end of the protrusion turn.

Optionally, the reset piece is connected with the second connecting portion of the top piece, so that the top of the top piece can be switched and maintained in the falling position by the force acting on the second connecting portion of the top piece by the reset piece. Of course, in another feasible embodiment, the reset piece can also be connected to any position between the first connecting part and the second connecting part of the top piece, and the reset force exerted on the top piece can make the top piece rotate to make the top piece rotate. Switch the top and keep it in the drop position.

Optionally, in another feasible embodiment, the structure of the electric drive assembly is not limited to the above structure. For example, in another feasible embodiment, the electric drive assembly includes a movable member disposed on the bottom frame and a motor for driving the movable member to move, and the movable member moves to drive the second connecting portion of the top member to move.

Specifically, optionally, the moving member can be driven by a motor to perform reciprocating movement, and the moving member moves to drive the second connecting portion of the top member to move. In a possible embodiment, for the top piece 450 shown in FIG. 17 , the moving piece can be driven to alternately abut and separate from the second connecting portion of the top piece in a direction parallel to the length direction of the top piece 450 . , to achieve the switch between the top jacking position and the falling position. In another feasible implementation manner, by disposing protrusions and depressions on the moving member, and driving the moving member to move, the top ends of the protrusions and the bottom ends of the depressions alternately abut against the second connecting portion of the top member, to drive the second connecting part of the top piece to move. Further, optionally, the protrusions and depressions are arranged in a direction parallel to the length direction of the top member 450 .

In this embodiment, the water outlet 430 and the valve core 2125 are provided independently, and the water outlet 430 is in contact with the valve core 2125 . It can be understood that, in another feasible embodiment, the water outlet and the valve core can also be integrally formed, or directly through the structure of the water outlet, so that the water outlet has an open and closed state of the valve core, so as to control the cup assembly 210 Whether the liquid in it flows out.

In this embodiment, when the water outlet 430 moves from the second position to the first position, the water outlet 430 drives the valve core 2125 to move in the same direction.

It should be noted that, in another feasible embodiment, when the water outlet moves from the second position to the first position, the valve core can also be driven to move in the opposite direction, that is, the valve core can be driven to move along the extending direction of the water outlet and away from the water outlet. The direction of the inner cavity of the cup assembly is moved. Correspondingly, after the valve core is separated from the driving force of the water outlet, it can automatically move in a direction along the extending direction of the water outlet and toward the inner cavity of the cup assembly. Specifically, a transmission mechanism such as a rack and pinion transmission can be used, so that when the water outlet nozzle drives the valve core to move, the water outlet nozzle and the valve core move in opposite directions.

For example, in a feasible embodiment, the valve core is integrally provided on the outer side of the cup assembly. And when it is not driven by the water outlet, the valve core is automatically sealed and fitted with the side wall of the water outlet of the cup body assembly or with the outer surface of the bottom wall of the cup body assembly, and the fitting position surrounds the water outlet, Thus, the water outlet of the cup assembly is sealed, that is, the valve core is closed. When the water outlet moves from the second position to the first position, the valve core is driven to move along the extending direction of the water outlet and away from the inner cavity of the cup body assembly, so that the valve core is out of contact with the cup body assembly, so that the cup body assembly The fluid inside can flow out through the water outlet, that is, the valve core is opened.

Referring to FIG. 24 to FIG. 27 , in this embodiment, the beverage machine 200 further includes a water collecting assembly 1 having a heat preservation effect. It can be understood that, conventionally, the water collecting assembly is used to receive the fluid spilled from the water cup or other utensils and the water outlet of the beverage machine. In this embodiment, the water collecting assembly 1 also has a heat preservation effect, so the water collecting assembly 1 can also heat and keep warm the water cup or other utensils placed on the water collecting assembly, so as to avoid the fluid in the water cup or other heat-conducting utensils from being heated and insulated. The temperature drops rapidly. Therefore, the water collecting assembly 1 has the functions of heat preservation and water collecting at the same time.

In addition, since the water collecting cavity 1011 is sealed and isolated from the installation cavity 1013, it can prevent the heating element 102 in the installation cavity 1013 from being damp and the service life or heating effect of the heating element 102 due to the fluid flowing into the installation cavity 1013 by mistake, and the water and electricity are separated. Thus, the risk of short-circuit electric shock can be avoided.

Specifically, in this embodiment, the water collecting assembly 1 includes a water collecting box 101 and a heating assembly 102 . The water collection box 101 has a water collection cavity 1011 and an installation cavity 1013 sealed and isolated from the water collection cavity 1011 . The heating element 102 is arranged in the installation cavity 1013 . The heating element 102 generates heat to transfer the heat generated by the heating element 102 to the water cup or other utensils placed on the water collecting assembly 1 to avoid rapid temperature drop of the fluid in the water cup or other heat-conducting utensils.

Further, in a feasible embodiment, the heat generating component has pins that are hermetically connected to the mounting cavity. It can be understood that the pins on the heating element are used for direct or indirect connection with the power supply, so that the heating element can generate heat when powered on. The pins of the heating element are sealed with the installation cavity, which means that a sealing structure is provided around the pins to seal and isolate the heating element from other spaces in the installation cavity. Therefore, even if the fluid enters the mounting cavity, the contact between the fluid and the pins can be better avoided, thereby effectively avoiding the risk of short circuit of the internal circuit of the heating component.

Optionally, in a feasible embodiment, a sealing isolation sleeve is provided on the heating component, and the sealing isolation sleeve is sleeved on the pins, and seals and isolates the pins of the heating component from the installation cavity. Specifically, the sealing isolation sleeve may be a rubber sleeve or the like.

Optionally, in another feasible embodiment, the heating component includes a heating body, and the pins are electrically connected to the heating body. The heating body is provided with a pin isolation ring for sealing and isolating the pins and the mounting cavity. A pin isolation ring surrounds the pin setup. And one end or outer side wall of the pin isolation ring is sealingly connected with the mounting cavity, and the pins are sealed and isolated from the mounting cavity.

In this embodiment, the water collecting assembly 1 further includes a heat preservation placing table 103 . The heat preservation placing table 103 is arranged on the water collecting box 101 and is in thermal contact with the heating element 102 . Thereby, the water cup or other utensils can be placed on the heat preservation placing table 103 to prevent the water cup or other utensils from directly contacting the heating element, thereby preventing the fluid spilled from the water cup or other utensils from directly falling on the heating element, so as to reduce the heating element 102 The probability of getting wet can increase the service life of the heating element 102 .

In this embodiment, the water collecting box 101 has an inner cavity 1012 . The inner cavity 1012 of the water collecting box 101 is provided with a partition wall 1014 . The partition wall 1014 divides the inner cavity 1012 of the water collection box 101 into a water collection cavity 1011 and an installation cavity 1013 .

More specifically, in this embodiment, the installation cavity 1013 is surrounded by the water collecting cavity 1011 . It can be understood that, in another feasible embodiment, the installation cavity 1013 and the water collection cavity 1011 may also be arranged adjacently, or the installation cavity 1013 and the water collection cavity 1011 may be arranged separately.

In this embodiment, the mounting cavity 1013 has a top wall and a bottom wall. The heating element 102 is disposed on the top wall of the installation cavity 1013 and is spaced from the bottom wall of the installation cavity 1013 . The heating element 102 is arranged on the top wall of the installation cavity 1013 , so that the distance between the heating element 102 and the heat preservation placing table 103 is closer, and the heat emitted by the heating element 102 can be better transferred to the heat preservation placing table 103 more quickly. The heating element 102 is spaced from the bottom wall of the installation cavity 1013 . Therefore, even if the water collecting component 1 is damaged and the fluid such as water enters the installation cavity 1013, the heating component 102 can be prevented from directly contacting the fluid because the heating component 102 is directly spaced from the bottom wall of the installation cavity 1013. To avoid the heat-generating component 102 getting wet, and the risk of short circuit and electric shock.

Further, in this embodiment, the top wall of the installation cavity 1013 completely covers the heating element 102, and the top wall of the installation cavity 1013 has no gap. Therefore, the fluid flowing into the installation cavity 1013 can be prevented from falling onto the heating element 102, thereby preventing the heating element 102 from getting wet to a certain extent.

Further, in this embodiment, the heat preservation placing table 103, the partition wall 1014 and the cavity wall of the inner cavity 1012 of the water collecting box 101 enclose the installation cavity 1013; the surface of the heat preservation placing table 103 enclosing the installation cavity 1013 constitutes Mount the top wall of cavity 1013. In other words, the heating element 102 is directly disposed on the heat preservation placing table 103 , and the heating element 102 directly contacts the heat insulating placing table 103 , so that the heat emitted by the heating element 102 can be transferred to the heat preservation placing table 103 more quickly.

In this embodiment, the isolation wall 1014 is in the shape of a ring column. A sealing member is provided between the thermal insulation placing table 103 and the partition wall 1014 , so as to realize the sealing connection between the thermal insulation placing table 103 and the partition wall 1014 . Specifically, in the direction perpendicular to the extending direction of the sealing member, the section of the sealing member has a slot 1041 .

Among them, in this embodiment, the sealing member is a U-shaped sealing ring, and the upper end of the U-shaped sealing ring is fixed on the surface of the heat preservation placing table 103 surrounding the installation cavity 1013. The fixing method can be adhesive or other methods. There is no specific limitation in the embodiment. Optionally, the width of the slot 1041 of the seal can be slightly smaller than the width of the partition wall 1014 , so that the seal can fit more closely with the partition wall 1014 , so as to improve the connection between the thermal insulation placing table 103 and the partition wall 1014 . In order to prevent the fluid from flowing into the installation cavity 1013 through the connection position between the partition wall 1014 and the heat preservation placing table 103 .

Referring to FIG. 25 , in this embodiment, the water collecting box 101 is provided with a through groove 105 that communicates with the outside world and the installation cavity 1013 , and the heat preservation placing table 103 is arranged in the through groove 105 , so as to realize the sealing between the heat preservation placing table 103 and the partition wall 1014 Connect, and leave the heat preservation stand 103 exposed to allow the placement of cups or other utensils.

Further, in this embodiment, the heat preservation placing table 103 has a placing surface, and the placing surface of the heat preservation placing table 103 is lower than the surface of the water collecting box 101 provided with the through groove 105, so that the cup body or other utensils can be placed on the heat preservation place. While being placed on the table 103 , it can be embedded in the through groove 105 , so that the position of the cup body or other utensils can be defined by the through groove 105 .

In this embodiment, a plug 106 electrically connected to the heating element 102 is fixed on the water collecting box 101 . The beverage maker 200 also includes a socket 107 that mates with the plug 106 . The plug 106 is detachably connected to the socket 107 . Therefore, the disassembly of the water collecting assembly 1 is facilitated, thereby facilitating the discharge of the fluid collected in the water collecting box 101 . In addition, the connection between the plug 106 and the socket 107 can also ensure the phase position relationship between the water collecting assembly 1 and other structures of the beverage machine 200 to a certain extent, avoid any movement of the water collecting assembly 1, and ensure that the water collecting assembly 1 is placed on the water collecting box 101. The stability of the cup body or other utensils, etc., can be avoided, and the phenomenon of fluid leakage caused by the position deviation of the cup body or other utensils placed on the water collecting box 101 can be avoided.

Specifically, in this embodiment, a connection channel 108 is provided on the side wall of the water collecting box 101 , and the plug 106 is fixedly arranged in the connection channel 108 . In this way, the fluid is prevented from leaking out and falling onto the plug 106 , so as to avoid a short circuit phenomenon, and can avoid any movement of the water collecting assembly 1 .

Optionally, in a feasible embodiment, the beverage machine further includes a power adapter matched with the plug. Therefore, the water collecting assembly can be moved to any position as required, so that the cup or utensil placed on the heat preservation table can be easily accessed nearby. On the one hand, even if the cup or utensil is moved to another place, the water collecting assembly can be moved at the same time, so that the cup or utensil can still be placed on the water collecting assembly, so that the cup or utensil can be collected by the water collecting assembly. On the other hand, the setting of the power adapter makes it possible to realize the electrical connection between the water collecting assembly and the power supply through the power adapter even if the water collecting assembly is moved to another place, that is, the heating assembly can be made to work and realize the Thermal insulation effect, improve user experience effect.

Referring to FIG. 28 and FIG. 29 , in this embodiment, the water purification tank 204 has a closed water purification chamber 2041 . The water outlet 201 has a water outlet channel 2011 . The beverage machine 200 further includes a first air conduit 2042 whose two ends are in sealed communication with the water purification chamber 2041 and the water outlet channel 2011 respectively. The first air conduit 2042 can divert the steam flowing through the water outlet channel 2011 of the water outlet 201 into the water purification chamber 2041, thereby increasing the air pressure in the water purification tank 204, so as to avoid the occurrence of negative pressure in the water purification tank 204 and the occurrence of difficult pumping. out phenomenon. The water outlet channel 2011 is communicated with the atmosphere, and the first air conduit 2042 is communicated with the clean water tank 204. When the pressure in the clean water tank 204 is greater than the atmospheric pressure, the air pressure in the clean water tank 204 is balanced through the first air conduit 2042, so that the clean water tank 204 Internal air pressure balance.

In addition, it can be understood that the fluid flowing through the water outlet channel 2011 of the water outlet 201 has been purified, and the fluid does not come into contact with the outside world in the process of flowing out from the water purification chamber 2041 to the water outlet channel 2011 of the water outlet 201. Will not be polluted by the environment. Therefore, the vapor generated with the fluid is also not polluted. Therefore, the air pressure in the water purification chamber 2041 is balanced by the steam in the water outlet channel 2011 of the water outlet 201, and the purified water in the water purification chamber 2041 can be prevented from being polluted, thereby ensuring the purity of the purified water in the water purification chamber 2041.

Furthermore, the steam in the water outlet channel 2011 is drained into the water purification chamber 2041 through the first air guide pipe 2042 , thereby reducing the steam mixed in the purified water flowing out of the water outlet channel 2011 of the water outlet 201 , thereby making the water discharged through the water outlet 201 . The shape of the water flow of the purified water is stable, and there is no phenomenon such as swinging or splashing, which is convenient for users to take.

It can be understood that the first air conduit 2042 is used to drain steam, so in order to prevent the purified water in the water purification tank 204 from directly flowing into the water outlet channel 2011 of the water outlet 201 through the first air conduit 2042, the first air conduit 2042 It is connected to the position near the top of the water purification tank 204 to better avoid the contact between the first air conduit 2042 and the purified water in the water purification tank 204 .

In this embodiment, the water outlet 201 has an exhaust port 2013 that communicates with the water outlet channel 2011 , and one end of the first air conduit 2042 is sealed and sleeved on the exhaust port 2013 . That is, the first air conduit 2042 and the water outlet channel 2011 of the water outlet 201 are in a sealed connection by sealingly connecting the exhaust port 2013 and the first air conduit 2042 .

In this embodiment, the exhaust port 2013 has an exhaust channel 2014 communicating with the water outlet channel 2011 . The beverage maker 200 also includes a base plate assembly 205 . The exhaust channel 2014 extends in a direction perpendicular to the bottom plate assembly 205 , and the exhaust channel 2014 is located at the top of the water outlet 201 . Therefore, when the beverage machine 200 is in use, the bottom plate assembly 205 is located at the lower end of the beverage machine 200 , and the exhaust passage 2014 is located at the upper end of the water outlet 201 . In order to facilitate water collection, the outlet of the water outlet 201 is located at the lower end of the water outlet 201 . The purified water flowing through the water outlet 201 flows out from the outlet of the water outlet 201 under the action of gravity, instead of flowing into the exhaust channel 2014, so as to prevent the purified water in the water outlet channel 2011 of the water outlet 201 from passing through the exhaust port 2013 and the exhaust port 2013. The first air conduit 2042 flows into the clean water tank 204 .

Referring to FIG. 30 , in this embodiment, the heat preservation container 220 has a closed heat preservation cavity. The beverage machine 200 further includes a second air duct 2043 whose two ends are in sealed communication with the heat preservation cavity and the water purification cavity 2041 respectively. After the purified water pumped from the water purification chamber 2041 is heated and transported to the heat preservation chamber, the air pressure in the heat preservation chamber increases, and the air pressure in the water purification chamber 2041 decreases. At this time, the air pressure in the heat preservation chamber and the water purification chamber 2041 can be balanced by the arrangement of the second air conduit 2043 . That is, through the arrangement of the second air conduit 2043, on the one hand, it can avoid the phenomenon that the purified water in the water purification chamber 2041 is not easily pumped out due to the decrease in air pressure; to the insulation chamber.

Similarly, it can be understood that, in order to prevent the purified water in the water purification chamber 2041 from being transported to the heat preservation chamber through the second air conduit 2043, and also to prevent the purified water in the heat preservation chamber from being transported to the purified water through the second air conduit 2043 In the cavity 2041, one end of the second air duct 2043 is connected to the position near the top of the water purification tank 204, so as to better avoid the contact between the second air duct 2043 and the purified water in the water purification tank 204; The other end is connected to a position close to the top of the heat preservation chamber, so as to better avoid the contact between the second air conduit 2043 and the purified water in the heat preservation chamber.

In this embodiment, the first air duct 2042 and the second air duct 2043 are provided at the same time. Therefore, when the clean water in the water purification tank 204 is pumped out and sent to the water outlet 201, the steam flowing through the water outlet channel 2011 of the water outlet 201 can be diverted to the water purification chamber 2041 through the first air conduit 2042, so as to avoid Negative pressure occurs in the clean water tank 204 to achieve air pressure balance in the clean water tank 204; when the clean water in the clean water tank 204 is pumped out for heating and transported to the insulation cavity, the water can be purified through at least the second air guide 2043 The air pressure balance in the cavity 2041 and the heat preservation cavity is achieved. When the air pressure balance in the water purification cavity 2041 and the heat preservation cavity cannot be achieved through the second air conduit 2043, the first air conduit 2042 is further combined to realize the air pressure in the water purification cavity 2041 and the heat preservation cavity. Air pressure balance.

As shown in FIGS. 31 and 32 , the second cup cover 214 includes a cover body 310 and a stopper 330 . The cover body 310 has a cover surface 311 . The blocking member 330 is in sealing contact with the cover surface 311 of the cover body 310 , and extends along a part of the edge of the cover surface 311 . The blocking member 330 and the cover surface 311 enclose the intercepting groove 320 .

It can be understood that the cover surface 311 of the cover body 310 refers to the surface of the cover body 310 exposed to the cavity of the second cup body 212 after the second cup cover 214 and the second cup body 212 are closed, that is, the cover A surface of one side of the body 310 close to the cavity of the second cup body 212 .

When the second cup cover 214 is removed from the second cup body 212, the side of the second cup cover 214 opposite to the stopper 330 may be lifted first, so that the liquid condensed on the cover surface 311 will follow When the cover body 310 is inclined to flow toward the edge of the cover surface 311 , it can be blocked by the blocking member 330 to intercept the flow in the intercepting groove 320 , thereby preventing the liquid from flowing out of the second cup body 212 .

In addition, the blocking member 330 extends along the edge of the covering surface 311 , so that the areas of the covering surface 311 that are not covered by the blocking member 330 are all located inside the blocking member 330 , so that the second cup cover 214 is removed from the second cup body. When it is removed from the top of 212 , the liquid condensed on the cover surface 311 can be blocked by the blocking member 330 so as to be intercepted in the intercepting groove.

Furthermore, if the temperature of the liquid contained in the second cup body 212 is relatively high, by preventing the liquid condensed on the cover surface 311 from flowing out of the second cup body 212, the liquid with a relatively high temperature can be prevented from flowing to the second cup. People, animals or plants in the vicinity are scalded outside the body 212 . If the liquid contained in the second cup 212 is corrosive or toxic, by preventing the liquid condensed on the cover surface 311 from flowing out of the second cup 212, the corrosive or toxic liquid can be prevented from flowing to the second cup 212. The outside of the cup body 212 pollutes the environment, and also prevents corrosive liquid from flowing out of the second cup body 212 to corrode surrounding objects, and avoids toxic liquid flowing out of the second cup body 212 to cause accidental contact between humans and animals and poisoning.

It can be understood that the stopper 330 is in sealing contact with the cover surface 311 of the cover body 310 , so as to prevent the liquid condensed on the cover surface 311 from flowing between the stopper 330 and the cover body 310 to the outside of the second cup body 212 s position. In addition, it can be understood that the stopper 330 is in sealing contact with the cover surface 311 of the cover body 310 , so the stopper 330 is protruded on the cover surface 311 of the cover body 310 , so that the stopper 330 can condense on the cover surface 311 . The liquid can be blocked by the blocking member 330 .

In this embodiment, the blocking member 330 has a blocking surface 331 located on the inner side. In other words, the blocking surface 331 of the blocking member 330 is the surface of the blocking member 330 for enclosing the intercepting groove 320 . The liquid condensed on the cover surface 311 flows to the blocking surface 331 of the blocking member 330 and is blocked.

In this embodiment, the cover body 310 and the blocking member 330 are integrally formed. It can be understood that, in another feasible embodiment, the cover body 310 and the blocking member 330 may also be provided separately. During assembly, the stopper 330 and the cover surface 311 of the cover body 310 can be sealed and fit.

In addition, in this embodiment, the cover body 310 and the blocking member 330 are made of the same material. Optionally, the cover body 310 may be a metal cover body such as a stainless steel cover body, or a plastic cover body such as a polypropylene cover body, a polycarbonate cover body, or a polyethylene plastic cover body. Correspondingly, the stopper 330 is formed of the same material as the cover body 310 , so that the cover body 310 and the stopper 330 can be integrally formed. It can be understood that, the cover body 310 and the blocking member 330 are formed of plastic material, which is low in cost and easy to form.

It can be understood that, in another feasible embodiment, the cover body and the blocking member may also be made of different materials, as long as the blocking member and the cover body can be sealed and fit.

Optionally, when the cover body 310 and the stopper 330 are made of different materials, the cover body 310 and the stopper 330 are adhesively connected, or a sealing gasket is provided between the cover body 310 and the stopper 330, so as to ensure the cover body The cover surface 311 of the 310 is in sealing contact with the blocking member 330 .

In the present embodiment, the blocking member 330 and the cover surface 311 enclose the intercepting groove 320 . The interception groove 320 is partially disposed around the edge of the cover surface 311 , so that the liquid trapped by the interception groove 320 can flow out from the end of the interception groove 320 by rotating the cover body 100 . During the specific operation, according to the position of the end of the interception groove 320 , the end of the interception groove 320 can be controlled to be located at the opening of the second cup body 212 , so that the liquid in the interception groove 320 can flow out.

In addition, in this embodiment, from the edge of the blocking surface 331 combined with the cover surface 311 to the free edge of the blocking surface 331 , the blocking surface 331 is gradually inclined in a direction away from the cover surface 311 . Therefore, after the second cup cover 214 is placed on the second cup body 212, the blocking surface 331 is inclined toward the inner cavity of the second cup body 212, so that the liquid in the interception groove 320 can flow into the second cup body relatively easily. 212.

In this embodiment, the projection of the blocking member 330 on the covering surface 311 includes a first edge 332 that is coincident with a quarter edge of the covering surface 311 and a second edge 334 located in the inner area of the covering surface 311 . The second side 334 is at least partially bent toward the direction of the first side 332 . It can be understood that the blocking member 330 has an outer surface 333 disposed opposite to the blocking surface 331 . The second side 334 is at least partially bent in the direction of the first side 332 , so that the area of the outer surface 333 is smaller, so that less liquid condenses on the baffle 331 , so as to avoid agglomeration of more liquid on the outer surface 333 As a result, the liquid flows out of the second cup body 212 . Moreover, the second side 334 is at least partially bent in the direction of the first side 332 , so that the blocking member 330 has a smaller volume and saves materials.

In this embodiment, the side of the second cup cover 214 has a first mounting structure 313 for rotatably connecting with the second cup body 212 . The blocking member 330 and the first mounting structure 313 are located on the same side of the cover surface 311 . Therefore, when the second cup cover 214 is opened, the blocking member 330 naturally follows the first installation structure 313 and is located at a lower position, so that the liquid condensed on the cover surface 311 can flow to the position pointing to the blocking member 330, and is further removed. The blocking member 330 is blocked into the intercepting groove. Therefore, by rotating the second cup cover 214 and the second cup body 212 , when the second cup cover 214 is opened, it is possible to prevent the second cup cover 214 from being inclined in the wrong direction, resulting in the flow of liquid condensed on the cover surface 311 . to the outside of the second cup body 212 .

In this embodiment, the blocking member 330 extends along a quarter edge of the cover surface 311 . It can be understood that, in another feasible embodiment, the blocking member may also be along one-fifth, one-quarter, one-third, one-half, two-thirds, and one-quarter of the cover surface. Three edge extensions. The longer the stopper extends along the edge of the cover surface, the longer the extension length of the intercepting groove enclosed by the stopper and the cover surface is, thereby increasing the range of directions in which the cover body can be tilted and facilitating the operation of the cover body. Preferably, the ratio of the extension length of the blocking member 330 to the extension length of the edge of the cover surface 311 is any ratio between one fifth and one half.

What's more, in a feasible embodiment, the blocking member may also be arranged around the cover joint surface. Therefore, when the cover body is opened from the second cup body 212, the cover body can be inclined in any direction, which can ensure that the liquid condensed on the cover surface can be blocked by the blocking member into the intercepting groove.

In this embodiment, the connecting position of the second cup cover 214 and the second cup body 212 is used to ensure the inclination direction of the second cup cover 214 when it is opened. In another feasible embodiment, the inclination direction of the cover body may also be ensured by other means.

As shown in FIG. 33 , the beverage machine provided by another embodiment of the present invention further includes a beverage storage container 2 that can be placed on the water collecting box 1 . Specifically, the beverage storage container 2 includes a first cup body 21 and a first cup cover 23 matched with the first cup body 21 . The first cup cover 23 has a water inlet hole 231 communicating with the cup cavity of the first cup body 21 . The beverage flowing out of the beverage processing mechanism can directly flow into the beverage storage container 2 through the water inlet hole 231 . On the one hand, through the setting of the first cup cover 23, dust in the environment can be prevented from falling into the beverage in the beverage storage container 2; It is simple, and there is no need to provide an operating space between the beverage processing mechanism and the beverage storage container 2 for the first cup cover 23 to be opened or removed, which satisfies the miniaturization requirement of the beverage machine.

The technical features of the above-described embodiments can be combined arbitrarily. For the sake of brevity, all possible combinations of the technical features in the above-described embodiments are not described. However, as long as there is no contradiction between the combinations of these technical features, All should be regarded as the scope described in this specification. The above-mentioned embodiments only represent several embodiments of the present invention, and the descriptions thereof are specific and detailed, but should not be construed as a limitation on the scope of the invention patent. It should be pointed out that for those skilled in the art, without departing from the concept of the present invention, several modifications and improvements can be made, which all belong to the protection scope of the present invention. Therefore, the protection scope of the patent of the present invention shall be subject to the appended claims.

Claims

A beverage machine (200), characterized in that it includes:

a water purification mechanism, comprising a filter assembly (203), and a water purification tank (204) connected to the water outlet end of the filter assembly (203);

a heating mechanism (290) for heating the purified water flowing through the heating mechanism (290);

a beverage processing mechanism, including a cup assembly (210);

insulation container (220);

water outlet (201);

A water pump assembly, comprising a first water pump (250) for pumping out the clean water in the clean water tank (204) and flowing through the heating mechanism (290), and a first water pump (250) for pumping the clean water in the heat preservation container (220) The second water pump (280) of the heating mechanism (290) is pumped out and flows through the heating mechanism (290);

A valve assembly (230) can selectively control the delivery of purified water flowing through the heating mechanism (290) to the water outlet (201), the cup assembly (210) or the heat preservation container (220).
The beverage machine (200) according to claim 1, further comprising a cover (202), the cover (202) having an inner cavity, the water purification mechanism, the heating mechanism (290), The heat preservation container (220), the water pump assembly and the valve assembly (230) are all located in the inner cavity of the casing (202); the casing (202) includes a front panel (2022), and the front The panel (2022) has an inwardly recessed recessed area (2023); the beverage processing mechanism is located on the outer surface of the recessed area (2023) of the front panel (2022).
The beverage machine (200) according to claim 2, wherein the heating mechanism (290) is located on the inner side of the front panel (2022) and is disposed adjacent to the front panel (2022).
The beverage machine (200) according to claim 2, wherein the heat preservation container (220) is located inside the front panel (2022), and is disposed adjacent to the front panel (2022);

The housing (202) further includes a first side panel (2024) adjacent to the front panel (2022); the first water pump (250) is located inside the first side panel (2024) and is connected to the first side panel (2024). The second water pump (280) and the first side panel (2024) are arranged adjacent to each other; the clean water tank (204) is located on the inner side of the front panel (2022), and is connected to the front panel (2022) ) adjacent to the setting.

The heating mechanism (290), the heat preservation container (220) and the water pump assembly are all located on the bottom side of the clean water tank (204).

It also includes a bottom plate assembly (205) and a raw water tank installation position (2051); the raw water tank installation position (2051) and the cover (202) are both fixed on the bottom plate assembly (205); the raw water tank The installation position (2051) is arranged adjacent to the casing (202), and the original water tank installation position (2051) is located on the side of the casing (202) away from the front panel (2022);

Along the arrangement direction of the raw water tank installation position (2051) and the cover (202) on the bottom plate assembly (205), the filter assembly (203) is located between the clean water tank (204) and the between the original water tank installation positions (2051).
The beverage machine (200) according to claim 1, wherein the valve assembly (230) comprises:

A main body (110), the main body (110) having a first cavity (111), a second cavity (112), a first cavity (111) and a second cavity (112) communicating with the first cavity (111) a communication channel (114), a water inlet (116) communicated with the first cavity (111), a first water outlet (117) communicated with the first cavity (111), and a water inlet (117) communicated with the second cavity (111) a second water outlet (118) communicated with the cavity (112) and a third water outlet (119) communicated with the second cavity (112);

A first electromagnetic drainage unit, which can be switched between a first state and a second state; when the first electromagnetic drainage unit is in the first state, the first communication channel (114) is blocked, and the first water outlet ( 117) is connected to the first cavity (111); when the first electromagnetic drainage unit is in the second state, the first water outlet (117) is blocked, and the first cavity (111) is connected to the first water outlet (117). The second cavity (112) is conducted through the first communication channel (114); and

The second electromagnetic drainage unit can be switched between the third state and the fourth state; when the second electromagnetic drainage unit is in the third state, the third water outlet (119) is blocked, and the second water outlet ( 118) is connected to the second cavity (112); when the second electromagnetic drainage unit is in the fourth state, the second water outlet (118) is blocked, and the third water outlet (119) passes through the the second cavity (112) is turned on;

Wherein, the first water outlet (117) is communicated with the water outlet, the second water outlet (118) is communicated with the heat preservation container (220), and the third water outlet (119) is communicated with the cup The body assembly (210) is connected; when the water inlet (116) enters the water and the first electromagnetic drainage unit is in the first state, the first water outlet (117) discharges water, and the first water outlet (117) ) the outflowing water flows out from the water outlet (201); when the water inlet (116) enters the water, the first electromagnetic drainage unit is in the second state, and the second electromagnetic drainage unit is in the third state , the second water outlet (118) discharges water, and the water flowing out of the second water outlet (118) flows into the heat preservation container (220); water enters the water inlet (116), and the first electromagnetic drainage When the unit is in the second state and the second electromagnetic drainage unit is in the fourth state, water flows out of the third water outlet (119), and the water flowing out of the third water outlet (119) flows into the cup assembly ( 210).

The first electromagnetic drainage unit includes a first mover (131), a first coil (133) sleeved on the first mover (131), located in the first cavity (111) and connected with The first plug (135) and the first reset member (137) are fixedly connected to the first mover (131); the first coil (133) is not energized, and the first mover (131) is in Reset under the action of the first reset member (137), so that one of the first communication channel (114) and the first water outlet (117) is blocked by the first plug (135); The first coil (133) is energized, and the first mover (131) moves to drive the first plug (135) to move, so that the first communication channel (114) and the first Another water outlet (117) is blocked by the first plug (135);

And/or, the second electromagnetic drainage unit includes a second mover (151), a second coil (153) sleeved on the second mover (151), a second coil (153) located in the second cavity (112) ) and the second plug (155) and the second reset piece (157) fixedly connected with the second mover (151); the second coil (153) is not energized, the second mover (151) Reset under the action of the second reset member (157), so that one of the second communication channel (115) and the second water outlet (118) is blocked by the second plug (155). ) plugging; the second coil (153) is energized, and the second mover (151) moves to drive the second plug (155) to move, so that the second communication channel (115) and the The second water outlet (118) is blocked by the second plug (155).
The beverage machine (200) according to claim 1, wherein the beverage processing mechanism further comprises a water outlet seat (400) disposed on the bottom side of the cup body assembly; the water outlet seat (400) comprises:

chassis (410);

a water outlet (430), which is movably arranged on the bottom frame (410); the water outlet (430) moves to switch between a first position and a second position;

A top piece (450), having a first connecting portion (451) rotatably connected with the bottom frame (410), a second connecting portion (453) offset from the first connecting portion (451), and a second connecting portion (453) offset from the first connecting portion (451) the top part (455) of the first connecting part (451); the top part (450) can be rotated to make the top part (455) switch between the jacked up position and the retracted position; the top part (455) is controlled by the When the falling position is switched to the jacking position, the water outlet (430) is jacked up to the first position; when the top (455) is switched from the jacking position to the falling position, the water outlet (430) can be forced back to the second position; and

an electric drive assembly (470) for driving the second connecting portion (453) of the top piece (450) to move so that the top piece (450) is rotated until the top piece (455) is in a jacked-up position;

The bottom of the cup assembly (210) is provided with a water outlet (211) docking with the water outlet (430); the water outlet (211) is provided with a valve core (2125);

Wherein, when the water outlet (430) moves from the second position to the first position, the water outlet (430) drives the valve core (2125) to move in the first direction; the valve core is disengaged After the driving force of the water outlet (430), it can automatically move to the second direction; the first direction is the direction extending along the water outlet (211) and pointing to the inner cavity of the cup assembly (210). , one of the directions extending along the water outlet (211) and away from the inner cavity of the cup assembly (210), the second direction is extending along the water outlet (211) and pointing towards the The other of the direction of the inner cavity of the cup assembly (210) and the direction extending along the water outlet (211) and away from the inner cavity of the cup assembly (210).
The beverage machine (200) according to claim 1, further comprising a water collecting assembly (1) having a heat preservation effect.
The beverage machine (200) according to claim 7, wherein the water collecting assembly (1) comprises:

a water collection box (101), the water collection box (101) having a water collection cavity (1011) and an installation cavity (1013) sealed and isolated from the water collection cavity (1011);

A heating component (102), the heating component (102) is arranged in the installation cavity (1013); or, the heating component (102) is arranged on the installation cavity (1013), and the heating component has the same configuration as the installation cavity (1013). The mounting cavity is sealed to connect the pins.

The water collecting assembly (1) further comprises a heat preservation placing table (103); the heat preservation placing table (103) is arranged on the water collecting box (101) and is in thermal contact with the heating assembly (102).

The water collection box (101) has an inner cavity (1012); the inner cavity (1012) of the water collection box (101) is provided with a partition wall (1014); the partition wall (1014) separates the water collection box The inner cavity (1012) of (101) is divided into a water collecting cavity (1011) and an installation cavity (1013).

The installation cavity (1013) has a top wall (10131) and a bottom wall (10133); the heating element (102) is arranged on the top wall (10131) of the installation cavity (1013), and is connected with the installation cavity (1013) The bottom wall (10133) is spaced;

The heat preservation placing table (103), the partition wall (1014) and the cavity wall of the inner cavity (1012) of the water collecting box (101) enclose the installation cavity (1013); the heat preservation placing table (1014) The surface of 103) surrounding the installation cavity (1013) constitutes the top wall (10131) of the installation cavity (1013).

A plug (106) electrically connected to the heating component (102) is fixed on the water collecting box (101), and the beverage machine (200) further includes a socket (107) matching the plug (106) ; The plug (106) is detachably connected to the socket (107).

The water collecting assembly (1) further comprises a power adapter matched with the plug (106).

The water collecting assembly (1) further includes a beverage storage container (2) that can be placed on the water collecting box (101); the beverage storage container (2) includes a first cup body (21) and a drink storage container (21). The first cup cover (23) matched with the first cup body (21); the first cup cover (23) has a water inlet hole (231) that communicates with the cup cavity of the first cup body (21); so The beverage flowing out of the beverage processing mechanism can directly flow into the beverage storage container (2) through the water inlet hole (231).
The beverage machine (200) according to claim 1, wherein the water purification tank (204) has a closed water purification cavity (2041); the water outlet (201) has a water outlet channel (2011); The beverage machine (200) further comprises a first air conduit (2042) whose ends are in sealed communication with the water purification chamber (2041) and the water outlet channel (2011) respectively. The first air conduit (2042) can divert the steam flowing through the water outlet channel (2011) of the water outlet (201) into the water purification chamber (2041).

The water outlet (201) has an exhaust port (2013) communicating with the water outlet channel (2011), and one end of the first air conduit (2042) is sealed and sleeved on the exhaust port (2013).

The exhaust port (2013) has an exhaust channel (2014) communicating with the water outlet channel (2011); the beverage machine (200) further includes a bottom plate assembly (205); the exhaust channel (2014) is along the It extends perpendicular to the direction of the bottom plate assembly (205), and the exhaust channel (2014) is located at the top of the water outlet (201).

The heat preservation container (220) has a closed heat preservation cavity; the beverage machine (200) further includes a second air conduit (2043) whose ends are in sealed communication with the heat preservation cavity and the water purification cavity (2041), respectively.
The beverage machine (200) according to claim 1, wherein the cup body assembly (210) comprises a second cup body (212) and a second cup cover matched with the second cup body (212) (214); the second cup cover (214) includes:

a cover body (310), the cover body (310) having a cover surface (311); and

A blocking member (330) is sealingly fitted with at least a part of the edge of the cover joint surface (311) of the cover body (310); the blocking piece (330) and the cover joint surface (311) form a shut-off groove ( 320).